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To the Student In today’s world, knowing science is important for thinking critically, solving problems, and making decisions. But understanding science sometimes can be a challenge. South Carolina Science Essentials provides an opportunity for you to prepare for the state science assessment. Each lesson is correlated to one or more of the standards on the South Carolina Science Assessment Framework for Middle School Science. In each lesson: • Before You Read sparks your interest in what you’ll learn and relates it to your world. • Read to Learn describes important science concepts with words and graphics. Next to the text you can find a variety of study tips and ideas for organizing and learning information: • The Study Coach offers tips for getting the main ideas out of the text. • Foldables™ Study Organizers help you divide the information into smaller, easier-to-remember concepts. • Reading Checks ask questions about key concepts. The questions are placed so you know whether you understand the material. • Think It Over elements help you consider the material in-depth, giving you an opportunity to use your critical-thinking skills. • Picture This questions specifically relate to the art and graphics used with the text. You’ll find questions to get you actively involved in illustrating the concepts you read about. • Applying Math reinforces the connection between math and science. • Use After You Read to review key terms and answer questions about what you have learned. The Mini Glossary can assist you with science vocabulary. Review questions focus on the key concepts to help you evaluate your learning. See for yourself. South Carolina Science Essentials makes science easy to understand and enjoyable. Copyright © by the McGraw-Hill Companies, Inc. All rights reserved. Except as permitted under the United States Copyright Act, no part of this publication may be reproduced or distributed in any form or by any means, or stored in a database or retrieval system, without the prior written permission of the publisher. Send all inquiries to: Glencoe/McGraw-Hill 8787 Orion Place Columbus, OH 43240 ISBN-13: 978-0-07-875654-2 ISBN-10: 0-07-875654-5 Printed in the United States of America 2 3 4 5 6 7 8 9 10 009 09 08 07 Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Table of Contents Grade 6 South Carolina Science Academic Standards . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .vi Lesson A Living Things (6-2.1) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .1 Lesson B How are living things classified? (6-2.2) . . . . . . . . . . . . . . . . . . . .5 Lesson C Introduction to Plant Reproduction (6-2.3, 6-2.8) . . . . . . . . . . . .9 Lesson D Seed Reproduction (6-2.4, 6-2.5) . . . . . . . . . . . . . . . . . . . . . . . . .12 Lesson E Plant Responses (6-2.6) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .17 Lesson F Photosynthesis and Respiration (6-2.7) . . . . . . . . . . . . . . . . . . . .21 Lesson G Infectious Diseases (6-2.9) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .27 Lesson H What is an animal? (6-3.1) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .33 Lesson I Sponges, Cnidarians, Flatworms, and Roundworms (6-3.1, 6-3.2) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .37 Lesson J Mollusks and Segmented Worms (6-3.1, 6-3.2) . . . . . . . . . . . . .42 Lesson K Arthropods and Echinoderms (6-3.1, 6-3.2, 6-3.4, 6-3.5, 6-3.6)47 Lesson L Chordate Animals (6-3.1, 6-3.2, 6-3.3, 6-3.4, 6-3.5) . . . . . . . . . .51 Lesson M Amphibians and Reptiles (6-3.1, 6-3.2, 6-3.3, 6-3.4) . . . . . . . . .55 Lesson N Birds (6-3.1, 6-3.2) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .59 Lesson O Mammals (6-3.1, 6-3.2) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .62 Lesson P Types of Behavior (6-3.7) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .67 Lesson Q The Atmosphere (6-4.1, 6-4.2) . . . . . . . . . . . . . . . . . . . . . . . . . . .72 Lesson R Ocean Currents and Climates . . . . . . . . . . . . . . . . . . . . . . . . . . . .77 Lesson S Waves . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .82 Lesson T What is weather? (6-4.5) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .86 Lesson U Weather Patterns (6-4.4, 6-4.6) . . . . . . . . . . . . . . . . . . . . . . . . . . .93 Lesson V Weather Forecasts (6-4.6) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .101 Lesson W Earth's Weather (6-4.7, 6-4.8) . . . . . . . . . . . . . . . . . . . . . . . . . . .104 Lesson X Air Movement (6-4.9) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .111 Lesson Y What is energy? (6-5.1, 6-5.2) . . . . . . . . . . . . . . . . . . . . . . . . . . .117 Lesson Z Energy Transformations (6-5.1, 6-5.2) . . . . . . . . . . . . . . . . . . .122 Lesson AA Sources of Energy (6-5.1, 6-5.3, 6-5.4) . . . . . . . . . . . . . . . . . . .127 Lesson BB Electric Charge . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .137 Lesson CC Electric Current (6-5.4) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .143 Lesson DD Electricity Circuits (6-5.4) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .148 Lesson EE What is magnetism? . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .155 Lesson FF Heat (6-5.5) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .160 Lesson GG Work and Power (6-5.6) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .166 Lesson HH Using Machines (6-5.6) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .170 Lesson II Simple Machines (6-5.6, 6-5.7, 6-5.8) . . . . . . . . . . . . . . . . . . . .174 Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. South Carolina Science Academic Standards Grade 6 Standards Lesson Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Structures, Processes, and Responses of Plants Standard 6-2: The student will demonstrate an understanding of structures, processes, and responses of plants that allow them to survive and reproduce. (Life Science) 6-2.1 Summarize the characteristics that all organisms share (including the obtainment and use of resources for energy, A response to stimuli, the ability to reproduce, and process of physical growth and development). 6-2.2 Recognize the hierarchical structure of the classification (taxonomy) of organisms (including the seven major levels or B categories of living things—namely, kingdom, phylum, class, order, family, genus, and species). 6-2.3 Compare characteristic structures of various groups of plants (including vascular or nonvascular, seed or spore-producing, C flowering or cone-bearing, and monocot or dicot). 6-2.4 Summarize the basic functions of the structures of a flowering plant for defense, survival, and reproduction. D 6-2.5 Summarize each process in the life cycle of flowering plants (including germination, plant development, fertilization, D and seed production). 6-2.6 Differentiate between the processes of sexual and asexual reproduction of flowering plants. E 6-2.7 Summarize the processes required for plant survival (including photosynthesis, respiration, and transpiration). F 6-2.8 Explain how plants respond to external stimuli (including dormancy and forms of tropism known as phototropism, C, E gravitropism, hydrotropism, and thigmotropism). 6-2.9 Explain how disease-causing fungi can affect plants. G Structures, Processes, and Responses of Animals Standard 6-3: The student will demonstrate an understanding of structures, processes, and responses of animals that allow them to survive and reproduce. (Life Science) 6-3.1 Compare the characteristic structures of invertebrate animals (including sponges, segmented worms, echinoderms, H, I, J, K, L, M, N, O mollusks, and arthropods) and vertebrate animals (fish, amphibians, reptiles, birds, and mammals). 6-3.2 Summarize the basic functions of the structures of animals that allow them to defend themselves, to move, and to I, J, K, L, M, N, O obtain resources. 6-3.3 Compare the response that a warm-blooded (endothermic) animal makes to a fluctuation in environmental temperature L, M with the response that a cold-blooded (ectothermic) animal makes to such a fluctuation. 6-3.4 Explain how environmental stimuli cause physical responses in animals (including shedding, blinking, shivering, K, L, M sweating, panting, and food gathering). 6-3.5 Illustrate animal behavioral responses (including hibernation, migration, defense, and courtship) to environmental stimuli. L 6-3.6 Summarize how internal stimuli (including hunger, thirst, and sleep) of animals ensure their survival. K 6-3.7 Compare learned to inherited behaviors in animals. P Earth's Atmosphere and Weather Standard 6-4: The student will demonstrate an understanding of the relationship between Earth's atmospheric properties and processes and its weather and climate. (Earth Science) 6-4.1 Compare the composition and structure of Earth's atmospheric layers (including the gases and differences in temperature Q and pressure within the layers). 6-4.2 Summarize the interrelationships among the dynamic processes of the water cycle (including precipitation, evaporation, Q transpiration, condensation, surface-water flow, and groundwater flow). 6-4.3 Classify shapes and types of clouds according to elevation and their associated weather conditions and patterns. 6-4.4 Summarize the relationship of the movement of air masses high and low pressure systems, and frontal boundaries to U storms (including thunderstorms, hurricanes, and tornadoes) and other weather conditions. 6-4.5 Use appropriate instruments and tools to collect weather data (including wind speed and direction, air temperature, T humidity, and air pressure). South Carolina Science Academic Standards v Standards Lesson 6-4.6 Predict weather conditions and patterns based on weather data collected from direct observations and measurements, U, V weather maps, satellites, and radar. 6-4.7 Explain how solar energy affects Earth's atmosphere and surface (land and water). W 6-4.8 Explain how convection affects weather patterns and climate. W 6-4.9 Explain the influence of global winds and the jet stream on weather and climatic conditions. X Conservation of Energy Standard 6-5: The student will demonstrate an understanding of the law of conservation of energy and the properties of energy and work. (Physical Science) 6-5.1 Identify the sources and properties of heat, solar, chemical, mechanical, and electrical energy. Y, Z, AA 6-5.2 Explain how energy can be transformed from one form to another (including the two types of mechanical energy, Y, Z potential and kinetic, as well as chemical and electrical energy) in accordance with the law of conservation of energy. 6-5.3 Explain how magnetism and electricity are interrelated by using descriptions, models, and diagrams of electromagnets, AA generators, and simple electrical motors. AA, CC, DD FF GG, HH, II II II Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. 6-5.4 Illustrate energy transformations (including the production of light, sound, heat, and mechanical motion) in electrical circuits. 6-5.5 Illustrate the directional transfer of heat energy through convection, radiation, and conduction. 6-5.6 Recognize that energy is the ability to do work (force exerted over a distance). 6-5.7 Explain how the design of simple machines (including levers, pulleys, and inclined planes) helps reduce the amount of force required to do work. 6-5.8 Illustrate ways that simple machines exist in common tools and complex machines. vi South Carolina Science Academic Standards Llesson 3 A Living Things Standard 6-2.1: Summarize the characteristics that all organisms share (including the obtainment and use of resources for energy, response to stimuli, the ability to reproduce, and process of physical growth and development). Before You Read List three living things in your environment. What do these things need to live? Read to Learn Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. What are living things like? Any living thing is called an organism. Organisms vary in size from microscopic bacteria to giant trees. They are found just about everywhere. They have different behaviors and food needs. However, all organisms have similar traits. These traits determine what it means to be alive. What You’ll Learn the difference between living and nonliving things ■ what living things need to survive ■ Study Coach Create a Quiz As you study the information in this lesson, create questions about the information you read. Be sure to answer your questions. How are living things organized? Living things are made up of small units called cells. A cell is the smallest unit of an organism that carries on the functions of life. Some organisms are made up of just one cell. Others are made up of many cells. Cells take in materials from their surroundings. They use the materials in complex ways. Each cell has an orderly structure and has hereditary material. The hereditary material has instructions for cell organization and function. All the things organisms can do are possible because of what their cells can do. Explain Make a half sheet Foldable, as shown below, to list the traits of living organisms. Organisms How do living things respond? Living things interact with their surroundings. Anything that causes some change in an organism is a stimulus (plural, stimuli). The reaction to a stimulus is a response. Often that response results in movment. Made of cells Use energy Reproduce Grow Develop South Carolina Science Essentials 1 Place to live How do living things get energy? Identify Make a four-tab book, as shown below. On each flap identify things organisms need to live. Energy Food The energy that most organisms use to perform life activities comes from the Sun. Plants and some other organisms get energy directly from the Sun. They do this by combining sunlight with carbon dioxide and water to make food. People and most other organisms cannot use the energy of sunlight directly. Instead, they take in and use food as a source of energy. People get food by eating plants or other organisms that eat plants. Most organisms, including plants, must take in oxygen in order to release the energy of foods. Some organisms, such as bacteria that live at the bottom of the oceans where sunlight cannot reach, cannot use the Sun’s energy to make food. These organisms use chemical compounds and carbon dioxide to make food. They do not need oxygen to release the energy found in their food. How do living things grow and develop? Organisms grow by taking in raw materials. One-celled organisms grow by increasing in size. Most growth in manycelled organisms is due to an increase in the number of cells. Organisms change as they grow. All of the changes that take place during an organism’s life are called development. Complete development can take a few days for the butterfly shown below, or several years for a dog. The length of time an organism is expected to live is its life span. Some organisms have a short life span. Some have long life spans. Picture This 1. 2 Circle the animal that completes its development cycle in a few days. Lesson A Living Things Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Water Response to Stimuli To carry on its daily activity and to survive, an organism must respond to stimuli. Organisms respond to external stimuli such as movement and light. Living things also respond to stimuli that occur inside them. For example, water or food levels in organisms’ cells can increase or decrease. The organisms then make internal changes to keep the right amounts of water and food in their cells. An organism’s ability to keep the proper conditions inside no matter what is going on outside the organism is called homeostasis. Why do living things reproduce? Organisms eventually reproduce. They make more of their own kind. Some bacteria reproduce every 20 minutes. A pine tree might take two years to produce seeds. Without reproduction, living things would not exist to replace those individuals that die. 2. Explain Why do living things reproduce? 3. List three substances What do living things need? To survive, all living things need a place to live and raw materials. The places where they live and the raw materials they use can vary. In what places do organisms live? The environment limits where organisms can live. Not many organisms can live in extremely hot or extremely cold environments. Most cannot live at the bottom of the ocean or on the tops of mountains. All organisms need living space in their environment. For example, thousands of penguins build their nests on an island. The island becomes too crowded for all the penguins. They fight for space and some may not find space to build nests. An organism’s surroundings must provide for all its needs. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. What raw materials do organisms need? Water is important for all living things. Most organisms are made of more than 50 percent water. Humans are made of 60 to 70 percent water. Plants and animals take in and give off large amounts of water each day. Organisms use homeostasis to balance the amount of water taken in and lost. Organisms use water for many things. Blood is about 90 percent water. Blood transports food and wastes in animals. Plants use water to transport materials between roots and leaves. Living things are made up of substances such as sugars, proteins, and fats. Animals get these substances from the food they eat. Plants and some bacteria make the substances using raw materials from their surroundings. These important substances are used over and over again. When organisms die, substances from their bodies are broken down and released into the soil or air. The substances can then be used again by other organisms. found in living things. South Carolina Science Essentials 3 After You Read Mini Glossary cell: the smallest unit of an organism that carries on the functions of life homeostasis: an organism’s ability to regulate internal, life-maintaining conditions organism: any living thing 1. Review the terms and their definitions in the Mini Glossary. Write a sentence explaining how homeostasis works in humans. Traits of Living Things End of Lesson 4 Lesson A Living Things Visit msscience.com to access your textbook, interactive games, and projects to help you learn more about living things. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. 2. Complete the web diagram below by describing traits that tell what living things are like. Llesson 3 B How are living things classified? Standard 6-2.2: Recognize the hierarchical structure of the classification (taxonomy) of organisms (including the seven major levels or categories of living things—namely, kingdom, phylum, class, order, family, genus, and species). Before You Read List three living things in your environment. What do these things need to live? Read to Learn Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Classification When similar items are placed together, they are being classified. Organisms also are classified into groups. Early classifications of organisms included grouping plants that were used in medicines. Animals were often classified by human traits. For example, lions were classified as courageous animals and owls were classified as wise. More than two thousand years ago, Aristotle, a Greek, decided that any organism could be classified as either a plant or an animal. Then he broke these two groups into smaller groups. For example, his groups included animals that had hair and animals that did not have hair, and animals with and without blood. Who was Carolus Linnaeus? In the late 1700s, Carolus Linnaeus, a Swedish naturalist, developed a new system of grouping organisms. His system was based on organisms with similar structures. For example, plants that had a similar flower structure were grouped together. His system was accepted and used by most other scientists. What You’ll Learn how early scientists classified living things ■ how similarities are used to classify organisms ■ the system of binomial nomenclature ■ how to use a dichotomous key ■ Study Coach Ask and Answer Questions Read each subhead. Then work with a partner to write questions about the information in each subhead. Take turns asking and answering the questions. 1. Describe the system used by Linnaeus to group organisms. South Carolina Science Essentials 5 What classification do modern scientists use? Modern scientists also use similarities in structure to classify organisms. They also use similarities in both external and internal features. For example, scientists use the number of chromosomes in cells to understand which organisms may be genetically related to each other. In addition, scientists study fossils, hereditary information, and early stages of development. Scientists use the information to determine an organism’s phylogeny. Phylogeny (fi LAH juh nee) is the organism’s evolutionary history. This tells how the organism has changed over time. It is the basis for the classification of many organisms. Explain What can you learn from the phylogeny of an organism? How are organisms grouped? A classification system commonly used today groups organisms into six kingdoms. A kingdom is the first and largest category. Kingdoms are divided into smaller groups. The smallest classification is a species. Organisms in the same species can mate and produce fertile offspring. The figure below shows how a bottle-nosed dolphin can be classified. Kingdom Phylum Picture This 3. Classify Circle the names of the kingdom and species of the bottle-nosed dolphin. Animalia Chordata Class Mammalia Order Cetacea Family Genus Delphinidae Tursiops Species –Tursiops truncatus Scientific Names If scientists used only common names of organisms, it would be confusing. For example, a jellyfish is neither a fish nor jelly. A sea lion is more closely related to a seal than a lion. To avoid confusion, scientists use a naming system developed by Linnaeus when referring to a particular species. Each species has a unique, two-word scientific name. 6 Lesson B How are living things classified? Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. 2. What is binomial nomenclature? The two-word naming system used to name organisms is called binomial nomenclature (bi NOH mee ul · NOH mun klay chur). The first word of the two-word name identifies the genus of the organism. A genus is a group of similar species. The second word of the name might tell you something about the organism. It might tell what it looks like or where it is found. Why are scientific names used? 4. Explain What does the first word in an organism’s binomial nomenclature indicate? Two-word scientific names are used for four reasons. • They help avoid mistakes. • Animals with similar evolutionary history are classified together. • Scientific names give descriptive information about the species. • Scientific names allow information about organisms to be organized easily and efficiently. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Tools for Identifying Organisms Tools used to identify organisms include field guides and dichotomous (di KAH tuh mus) keys. Field guides include descriptions and pictures of organisms. They give information about where each organism lives. You can use a field guide to identify species from around the world. What are dichotomous keys? 5. List two tools that can be used to identify organisms. A dichotomous key is a detailed list of identifying characteristics that includes scientific names. The keys are set up in steps. Each step has two descriptive statements, such as hair or no hair. You can use a dichotomous key, such as the one below, to identify and name a species. 1. Tail hair 2. Ear size 3. Tail length 4. Tail coloration Key to Some Mice of North America a. no hair on tail; scales show plainly; house mouse, Mus musculus b. hair on tail, go to 2 a. ears small and nearly hidden in fur, go to 3 b. ears large and not hidden in fur, go to 4 a. less than 25 mm; woodland vole, Microtus pinetorum b. more than 25 mm; prairie vole, Microtus ochrogaster a. sharply bicolor, white beneath and dark above; deer mouse, Peromyscus maniculatus b. darker above than below but not sharply bicolor; white-footed mouse, Peromyscus leucopus Picture This 6. Identify the mouse that has a mostly dark, hairy tail and large ears. South Carolina Science Essentials 7 After You Read Mini Glossary binomial nomenclature (bi NOH mee ul · NOH mun klay chur): the two-word naming system used to name organisms genus: a group of similar species kingdom: the first and largest category of organisms phylogeny (fi LAH juh nee): the evolutionary history of an organism 1. Review the terms and their definitions in the Mini Glossary. Choose one of the terms and explain its role in classifying organisms. 2. Complete the diagram below by explaining what binomial nomenclature is and the reasons for using it. Binomial Nomenclature Reasons for Using Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. What is it? End of Lesson 8 Lesson B How are living things classified? Visit msscience.com to access your textbook, interactive games, and projects to help you learn more about how living things are classified. Llesson 3 C Introduction to Plant Reproduction Standard 6-2.3: Compare the characteristic structures of various groups of plants (including vascular or nonvascular, seed or spore-producing, flowering or cone-bearing, and monocot or dicot). Standard 6-2.8: Explain how plants respond to external stimuli (including dormancy and forms of tropism known as phototropism, gravitropism, hydrotropism, and thigmotropism). Before You Read List four things you need to survive. Then circle the items on your list that you think plants also need to survive. Read to Learn Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Types of Reproduction What do humans and plants have in common? Both need water, oxygen, energy, and food to grow. Like humans, plants reproduce and make similar copies of themselves. Most plants can reproduce in two different ways—by sexual reproduction and by asexual reproduction. What You’ll Learn the differences between the two types of plant reproduction ■ the two stages in a plant’s life cycle ■ Identify Main Ideas Underline the important ideas in this lesson. Review these ideas as you study the lesson. What happens in asexual plant reproduction? Asexual reproduction does not require the production of sex cells. Instead, one organism produces a new organism that is genetically identical to it. Under the right conditions, an entire plant can grow from one leaf or part of a stem or root. When growers use these methods to start new plants, they must make sure that the plant part has plenty of water and anything else it needs to survive. The stems of lawn grasses grow underground and produce new grass plants asexually along the length of the stem. What is sexual plant reproduction? 1. Analyze A cutting from a plant can be placed in water and roots grow. Is this an example of asexual or sexual reproduction? Explain your answer. Sexual reproduction in plants requires the production of sex cells—usually called sperm and eggs—in reproductive organs. The organism produced by sexual reproduction is genetically different from either parent organism. South Carolina Science Essentials 9 Fertilization An important part of sexual reproduction is fertilization. Fertilization happens when a sperm and egg combine to produce the first cell of the new organism, the zygote. In plants, water, wind, or animals help bring the sperm and the egg together. What reproductive organs do plants have? A plant’s female reproductive organs produce eggs. The male reproductive organs produce sperm. Some plants have both reproductive organs. A plant with both reproductive organs can usually reproduce by itself. Other plants have either female or male reproductive organs. For fertilization to happen, the male and female plants must be near each other. Plant Life Cycles book, as shown below. Explain the two stages of the plant life cycle. Haploid Diploid Gametophyte Stage Sporophyte Stage A plant has a life cycle with two stages—the gametophyte (guh MEE tuh fite) stage and the sporophyte (SPOHR uh fite) stage. The figure below shows the two stages. Gametophyte Stage When reproductive cells undergo meiosis and produce haploid cells called spores, the gametophyte stage begins. Spores divide by cell division to form plant structures or an entire new plant. The cells in these structures or plants are haploid and have half a set of chromosomes. Some of these cells undergo cell division and form sex cells. Sporophyte Stage Fertilization—the joining of haploid sex cells—begins the sporophyte stage. Cells formed in this stage are diploid and have the full number of chromosomes. Meiosis in some of these cells forms spores, and the cycle repeats. Picture This 2. Identify Write the name of the stage that begins with meiosis below the word Meiosis. Write the name of the stage that begins with fertilization above the word Fertilization. Fertilization Sex cells (sperm and eggs) (n) Gametophyte plant structures (n) Haploid Diploid Spores (n) Meiosis 10 Lesson C Introduction to Plant Reproduction Sporophyte plant structures (2n) Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Explain Make a shutterfold After You Read Mini Glossary gametophyte (guh MEE tuh fite) stage: the stage in plant reproduction when reproductive cells undergo meiosis spores: haploid cells produced in the gametophyte stage sporophyte (SPOHR uh fite) stage: the stage in plant reproduction when fertilization begins 1. Review the terms and their definitions in the Mini Glossary. Write a sentence that explains the difference between the gametophyte stage and the sporophyte stage. 2. Choose one of the question headings in the Read to Learn section. Write the question in the space below. Then write your answer to that question on the lines that follow. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Write your question here. 3. Fill in the table below with either “yes” or “no” to compare asexual and sexual reproduction in plants. Asexual Reproduction Sexual Reproduction a. Requires production of sex cells? b. Produces organism that is genetically identical to parent? c. Requires fertilization? Visit msscience.com to access your textbook, interactive games, and projects to help you learn more about the basics of plant reproduction. End of Lesson South Carolina Science Essentials 11 Llesson 3 D Seed Reproduction Standard 6-2.4: Summarize the basic functions of the structures of a flowering plant for defense, survival, and reproduction. Standard 6-2.5: Summarize each process in the life cycle of flowering plants (including germination, plant development, fertilization, and seed production). What You’ll Learn the life cycles of most gymnosperms and angiosperms ■ the structure and function of the flower ■ the ways seeds are scattered ■ Study Coach Before You Read On the lines below, write the names of three fruits or vegetables. Next to each name, describe its seed. Read to Learn Define Terms Skim the text The Importance of Pollen and Seeds All plants described so far have been seedless plants. However, the fruits and vegetables that you eat come from seed plants. Oak, maple, and other shade trees also are produced by seed plants. All flowers are produced by seed plants. In fact, most plants on Earth are seed plants. Reproduction that involves pollen and seeds helps explain why seed plants are so successful. What is pollen? 1. Identify one way a pollen grain reaches the female part of the plant. 12 Lesson D Seed Reproduction In seed plants, some spores develop into small structures called pollen grains. A pollen grain has a waterproof covering and contains gametophyte parts that can produce sperm. The waterproof covering of a pollen grain can be used to identify the plant that the pollen grain came from. The sperm of seed plants are carried as part of the pollen grain by gravity, wind, water, or animals. The transfer of pollen grains to the female part of the plant is called pollination. After the pollen grain reaches the female part of the plant, a pollen tube is produced. The sperm moves through the pollen tube, then fertilization can happen. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. and write each key term on an index card. As you read the lesson, write the definition of each term on another index card. Use the cards to match the terms to their definitions as you review the important words in this lesson. What are the three main parts of a seed? After fertilization, the female part can develop into a seed. As shown in the figure below, a seed has three main parts, an embryo, stored food, and a protective seed coat. The embryo will grow to become the plant’s stem, leaves, and roots. The stored food gives the embryo energy when it begins to grow into a plant. Because a seed contains an embryo and stored food, a new plant develops faster from a seed than from a spore. Picture This 2. Stored food Infer Circle the part of the seed that will become a plant. Embryo Seed coat Gymnosperms and Angiosperms Gymnosperms (JIHM nuh spurmz) and angiosperms are the two groups of seed plants. In gymnosperms, seeds usually develop in cones. In angioperms, seeds develop in flowers and fruit. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Gymnosperm Reproduction Cones are the reproductive structures of gymnosperms. Gymnosperm plants include pines, firs, cedars, cycads, and ginkgoes. Each kind of gymnosperm has a different cone. A pine tree is a gymnosperm. The way pines produce seeds is typical of most gymnosperms. The pine is a sporophyte plant that produces both male cones and female cones. Male and female gametophyte structures are produced in the cones, but they are very small. A mature female cone is made up of woody scales on a short stem. At the base of each scale are two ovules. The egg is produced in the ovule. Pollen grains are produced in the smaller male cones. In the spring, clouds of pollen are released from the male cones. How are gymnosperm seeds produced? Pollen is carried from the male cones to the female cones by the wind. The pollen must land between the scales of a female cone to be useful. There it can be trapped in the sticky fluid given off by the ovule. If the pollen grain and the female cone are the same species, fertilization can take place. It can take from two to three years for the seed to develop. Categorize Make a folded chart, as shown below. Write facts in each block to describe the reproduction of gymnosperms and angiosperms. South Carolina Science Essentials 13 Angiosperm Reproduction Identify the four main parts of a flower. Picture This 4. Stigma Locate Highlight the male reproductive structure. Circle the female reproductive structure. Anther Pistil Stamen Filament Style Ovary Ovule Sepal Scarlet pimpernel How is pollen spread? Insects and other animals eat the flower, its nectar, or pollen. As insects and other animals move about the flower, they get pollen on their body parts. These animals spread the flower’s pollen to other plants they visit. Some flowers depend on the wind, rain, or gravity to spread their pollen. Following pollination and fertilization, the ovules of flowers can develop into seeds. 14 Lesson D Seed Reproduction Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. 3. Most seed plants are angiosperms. All angiosperms have flowers, which are the reproductive organs. Flowers have gametophyte structures that produce sperm or eggs for sexual reproduction. Most flowers have four main parts—petals, sepals, stamen, and pistil, as shown in the figure below. The petals usually are the most colorful parts of the flower. Sepals often are small, green, leaflike parts. In some flowers, the sepals are as colorful and as large as the petals. Inside the flower are the reproductive organs of the plant. The stamen is the male reproductive organ of the plant. The stamen has a thin stalk called a filament. On the end of the filament is an anther. Pollen grains form inside the anther. Sperm develop in each pollen grain. The pistil is the female reproductive organ. It consists of a stigma, a long stalklike style, and an ovary. Pollen grains land on the stigma and move down the style to the ovary. The ovary is the swollen base of the pistil where the ovules are found. Eggs are produced in the ovules. Not all flowers have both male and female reproductive parts. How do angiosperm seeds develop? A flower is pollinated when pollen grains land on a pistil. A pollen tube grows from the pollen grain. The pollen tube enters the ovary and reaches an ovule. The sperm then travels down the pollen tube and fertilizes the egg in the ovule. A zygote forms and grows into a plant embryo. Parts of the ovule develop into the stored food and the seed coat that surround the embryo, and a seed is formed. The seeds of some plants, like beans and peanuts, store food in structures called cotyledons. The seeds of other plants, like corn and wheat, store food in a tissue called endosperm. 5. Identify Where is the egg fertilized? Seed Dispersal Some plant seeds are spread by gravity. They fall off the parent plant. Other seeds have attached structures, like wings or sails, which help the wind carry them. Some seeds are eaten by animals and spread after the seeds are digested. Other seeds are stored or buried by animals. Raindrops can knock seeds out of dry fruit. Some fruits and seeds float on flowing water or ocean currents. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. What is germination? A series of events that results in the growth of a plant from a seed is called germination. Seeds will not germinate until the environmental conditions are right. Conditions that affect germination include temperature, light, water, and oxygen. Germination begins when seed tissues absorb water. This causes the seed to get larger and the seed coat to break open. As you can see in the figure below, a root eventually grows from the seed. Then a stem and leaves grow. Once the plant grows above the soil, photosynthesis begins. Photosynthesis provides food as the plant continues to grow. Picture This First leaf Cotyledon Seed coat Endosperm Cotyledons Seed coat 6. Locate Highlight the structure in each plant that stores food. In beans, the cotyledons rise above the In corn, the stored food in the soil. As the stored food is used, the endosperm remains in the soil and is cotyledons shrivel and fall off. gradually used as the plant grows. South Carolina Science Essentials 15 After You Read Mini Glossary germination: a series of events that result in the growth of a plant from a seed ovary: the swollen base of the pistil where ovules are found ovule: the place where eggs are produced pistil: the female reproductive organ in the flower of an angiosperm pollen grain: a small structure in seed plants that has a waterproof covering and that contains gametophyte parts that can produce sperm pollination: the transfer of pollen grains to the female part of the plant stamen: the male reproductive organ in the flower of an angiosperm 1. Review the terms and their definitions in the Mini Glossary. Write a sentence that describes either the male or the female reproductive organs of a flower. 2. Complete the concept web below to identify the ways seeds are spread. Ways Seeds Are Spread c. End of Lesson 16 Lesson D Seed Reproduction d. Visit msscience.com to access your textbook, interactive games, and projects to help you learn more about seed reproduction in plants. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. b. a. gravity Llesson E3 Plant Responses Standard 6-2.6: Differentiate between the process of sexual and asexual reproduction of flowering plants. Before You Read Have you ever been suddenly surprised? On the lines below, describe what surprised you and how your body responded to the surprise. Read to Learn Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. What are plant responses? A stimulus is anything in the environment that causes a response in an organism. A stimulus may come from outside (external) or inside (internal) the organism. An outside stimulus could be something that startles or surprises you. An inside stimulus is usually a chemical produced by the organism. Many of these chemicals are hormones. Hormones are substances made in one part of an organism for use somewhere else in the organism. The response to the stimulus often involves movement toward or away from the stimulus. All living organisms, including plants, respond to stimuli. What You’ll Learn the relationship between a stimulus and a tropism in plants ■ about long-day and short-day plants ■ how plant hormones and responses are related ■ Study Coach Create a Quiz Write a quiz question for each paragraph. Answer the question with information from the paragraph. Tropisms Some plant responses to external stimuli are called tropisms (TROH pih zumz). A tropism can be seen as movement caused by a change in growth. It can be positive or negative. A positive tropism would be growth toward a stimulus. A negative tropism would be growth away from a stimulus. You may have seen plants responding to touch, light, and gravity. Plants also can respond to electricity, temperature, and darkness. Compare Make a two-tab Foldable, as shown below, to compare inside and outside stimuli. Inside Stimuli Outside Stimuli South Carolina Science Essentials 17 Explain Make a two-tab concept map Foldable, as shown below, to describe and list positive and negative tropisms. Touch If a pea plant touches a solid object, it responds by growing faster on one side of its stem than on the other side. As a result, the stem bends and twists around any object it touches. Light When a plant responds to light, the cells on the side of the plant opposite the light get longer than the cells facing the light. Because of this, the plant bends toward the light. The leaves turn and can absorb more light. This positive response to light is called positive phototropism. Gravity Plants respond to gravity. The downward growth of plant roots is a positive response to gravity. A stem growing upward is a negative response to gravity. Plant Hormones Plants have hormones that control the changes in growth that result from tropisms and affect other plant growth. These hormones include ethylene, auxin, gibberellin, cytokinin, and abscisic acid. Many plants produce the hormone ethylene (EH thuh leen) gas and release it into the air around them. This hormone helps fruits ripen. Ethylene also causes a layer of cells to form between a leaf and the stem. The cell layer causes the leaf to fall from the stem. What is auxin? The plant hormone auxin (AWK sun) causes a positive response to light in stems and leaves. The figure below shows the effect of auxin. When light shines on a plant from one side, the auxin moves to the shaded side of the stem where it causes a change in growth. Auxin causes plants to grow toward light. Picture This 1. Describe Use the figure to describe to a partner how auxin affects a plant’s response to light. Light Cells on shaded side grow longer. Lack of auxin on lighted side Auxin moves to shaded side 18 Lesson E Plant Responses Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. How does ethylene affect plants? How do gibberellins and cytokinins affect plant growth? Two other groups of plant hormones also affect a plant’s growth. Gibberellins (jih buh REH lunz) can be mixed with water and sprayed on plants and seeds to stimulate plant stems to grow and seeds to germinate. Cytokinins (si tuh KI nunz) promote growth by causing faster cell division. Cytokinins can keep stored vegetables fresh longer. 2. Explain How does abscisic acid affect plants? 3. Infer Why could you How does abscisic acid affect plant growth? Abscisic (ab SIH zihk) acid is a plant hormone that keeps seeds from sprouting and buds from developing during the winter. This hormone also causes stomata to close in response to water loss on hot summer days. Photoperiods A plant’s response to the number of hours of daylight and darkness it receives daily is called photoperiodism (foh toh PIHR ee uh dih zum). Because Earth is tilted about 23.5° from a line perpendicular to its orbit, the hours of daylight and darkness change with the seasons. These changes in the length of daylight and darkness affect plant growth. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. How does darkness affect flowers? Many plants must have a certain length of darkness to flower. Plants that need less than 10 h to 12 h of darkness to flower are called long-day plants. These plants include spinach, lettuce, and beets. Plants that need 12 or more hours of darkness to flower are called short-day plants. These plants include poinsettias, strawberries, and ragweed. If a short-day plant receives less darkness than it needs to flower, it will produce larger leaves instead of flowers. What are day-neutral plants? Plants that do not need a set amount of darkness to flower are called day-neutral plants. They can flower within a range of hours of darkness. These plants include dandelions and roses. Knowing the photoperiods of plants helps farmers and gardeners know which plants will grow best in the area where they live. produce long-day flowering plants in a greenhouse during winter months? South Carolina Science Essentials 19 After You Read Mini Glossary auxin (AWK sun): a plant hormone that causes plant stems and leaves to exhibit positive response to light day-neutral plant: a plant that does not have a specific photoperiod to flower long-day plant: a plant that needs less than 10 h to 12 h of darkness to flower photoperiodism (foh toh PIHR ee uh dih zum): a plant’s response to the number of hours of daylight and darkness it receives daily short-day plant: a plant that needs 12 h or more of darkness to flower tropism (TROH pih zum): a response of a plant to an external stimulus 1. Review the terms and their definitions in the Mini Glossary. Write one or two sentences to explain the differences among the long-day, short-day, and day-neutral plants. 2. Complete the cause-and-effect chart below to show how plant hormones affect plant growth. Effect Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Cause Ethylene Auxin Gibberellin Cytokinin End of Lesson 20 Lesson E Plant Responses Visit msscience.com to access your textbook, interactive games, and projects to help you learn more about plant responses. Llesson F3 Photosynthesis and Respiration Standard 6-2.7: Summarize the processes required for plant survival (including photosynthesis, respiration, and transpiration). Before You Read Name the parts of a plant that you have seen recently. For one of the parts, describe its function. What You’ll Learn how plants take in and give off gases ■ the differences and similarities between photosynthesis and respiration ■ why photosynthesis and respiration are important ■ Read to Learn Study Coach Summarize Main Ideas Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Taking in Raw Materials Plants make their own food using the raw materials water, carbon dioxide, and inorganic chemicals in the soil. Plants also produce wastes. Which plant structures move water into the plant? Read the lesson. Recall and write down the main ideas. Go back and check the main ideas to make sure they are accurate. Then use your notes to summarize the main ideas of this lesson. The figure below shows the plant structures that take in raw materials. Most of the water used by plants is taken in through the roots and moves through the plant to where it is used. Picture This 1. Identify Circle the raw materials that a plant takes in. South Carolina Science Essentials 21 What is the function of a leaf? Gas is exchanged in the leaves. Most of the water taken in by the roots of a plant exits the plant through its leaves. Carbon dioxide, oxygen, and water vapor enter and exit the plant through openings in the leaves. What is the structure of a leaf? Picture This 2. Identify Circle the part of the leaf where most of the plant’s food is made. Upper epidermis e Palisade layer Spongy layer Lower epidermis Why are chloroplasts important? 3. Describe What happens in the chloroplasts? 22 Lesson F Photosynthesis and Respiration Some cells of a leaf contain small green structures called chloroplasts. Chloroplasts are green because they contain a green pigment, or coloring, called chlorophyll (KLOR uh fihl). Chlorophyll is important to plants because the light energy that it absorbs is used to make food. This food-making process, photosynthesis (foh toh SIHN thuh suhs), happens in the chloroplasts. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. A leaf is made up of many different layers. The outer layer of the leaf is called the epidermis. The epidermis is nearly transparent and allows sunlight, which is used to make food, to reach the cells inside the leaf. The epidermis has many small openings called stomata (stoh MAH tuh) (singular, stoma). Raw materials such as carbon dioxide, water vapor, and waste gases enter and exit the leaf through the stomata. Many plants have stomata on their stems. Guard cells surround each stoma to control how much water enters and exits the plant. Stomata close when a plant is losing too much water. As you can see in the figure below, the inside of a leaf is made up of a spongy layer and a palisade layer. Carbon dioxide and water vapor fill the spaces of the spongy layer. Most of the plant’s food is made in the palisade layer. The Food-Making Process Photosynthesis is the process during which a plant’s chlorophyll traps light energy and sugars are produced. In plants, photosynthesis occurs only in cells with chloroplasts. For example, photosynthesis occurs only in a carrot plant’s green leaves. The carrot’s root cells do not have chlorophyll, so they cannot perform photosynthesis. But excess sugar produced in the leaves is stored in the root. The familiar orange carrot you eat is the root of the carrot plant. When you eat a carrot, you benefit from the energy stored as sugar in the plant’s root. Plants need light, carbon dioxide, and water for photosynthesis. The chemical equation for photosynthesis is shown below. Describe Use two quartersheets of notebook paper, as shown below, to take notes about photosynthesis. Light-dependent reactions Light-independent reactions chlorophyll 6CO2 6H2O light energy carbon dioxide water → C6H12O6 6O2 glucose oxygen Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. What are light-dependent reactions? Chemical reactions that occur during photosynthesis that need light are called the light-dependent reactions. During light-dependent reactions, chlorophyll and other pigments trap light energy that will be stored in sugar molecules. Light energy causes water molecules, which were taken up by the roots, to split into oxygen and hydrogen. The oxygen exits the plant through the stomata. This is the oxygen that you breathe. The hydrogen produced when water is split is used in light-independent reactions. What are light-independent reactions? Chemical reactions that occur during photosynthesis that do not need light are called light-independent reactions. The light energy trapped during the light-dependent reactions is used to combine carbon dioxide and hydrogen to make sugars, such as glucose. The chemical bonds that hold glucose and other sugars together are stored energy. What happens to the oxygen and glucose that are made during photosynthesis? Most of the oxygen produced during photosynthesis is a waste product and is released through the stomata. Glucose is the main form of food for plant cells. A plant usually produces more glucose than it can use. The extra glucose is stored in plants as other sugars and starches. When you eat carrots or potatoes, you are eating the stored product of photosynthesis. 4. List two other foods that are stored products of photosynthesis. South Carolina Science Essentials 23 How does a plant use glucose? Glucose also is the basis of a plant’s structure. Plants grow larger by taking in carbon dioxide gas and changing it to glucose. Cellulose, an important part of plant cell walls, is made from glucose. Leaves, stems, and roots are made of cellulose and other materials produced using glucose. Why is photosynthesis important? 5. Photosynthesis produces food. Photosynthesis uses carbon dioxide and releases oxygen. This removes carbon dioxide from the atmosphere and adds oxygen to it. Most organisms need oxygen to live. About 90 percent of the oxygen in the atmosphere today is a result of photosynthesis. Determine What does photosynthesis add to Earth’s atmosphere? The Breakdown of Food Respiration is a series of chemical reactions that breaks down food molecules and releases energy. Respiration that uses oxygen to break down food chemically is called aerobic respiration. The overall chemical equation for aerobic respiration is shown below. C6H12O6 6O2 glucose → oxygen 6CO2 6H2O energy carbon dioxide water Before aerobic respiration begins, glucose molecules in the cytoplasm are broken down into two smaller molecules. These molecules enter a mitochondrion, where aerobic respiration takes place. Oxygen is used to break down the molecules into water and carbon dioxide and to release energy. The figure below shows aerobic respiration in a plant cell. Picture This 6. Identify Circle the part of the cell where aerobic respiration occurs. Highlight the waste products of respiration. Mitochondrion Oxygen is used in the mitochondrion to break down these two molecules. O2 In the cytoplasm, each glucose molecule is broken down into two smaller molecules. 24 Lesson F Photosynthesis and Respiration Water and carbon dioxide are waste products of respiration. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Where does aerobic respiration occur? Why is respiration important? Food contains energy. But it is not in a form that can be used by cells. Respiration changes food energy into a form that cells can use. This energy drives the life processes of almost all organisms on Earth. Plants use energy produced by respiration to transport sugars, to open and close stomata, and to produce chlorophyll. When seeds sprout, they use energy from the respiration of stored food in the seed. The figure below shows some uses of energy in plants. Picture This Plant structure and function 7. List two uses of energy produced by respiration in plants. Production of chlorophyll Sprouting of seeds Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. The waste product carbon dioxide also is important. Aerobic respiration returns carbon dioxide to the atmosphere, where plants and some other organisms use it for photosynthesis. Comparison of Photosynthesis and Respiration Aerobic respiration is almost the reverse of photosynthesis. Photosynthesis combines carbon dioxide and water by using light energy. The end products are glucose (food) and oxygen. Aerobic respiration combines oxygen and food to release the energy in the chemical bonds of the food. The end products of aerobic respiration are energy, carbon dioxide, and water. Look at the table below to compare the differences between photosynthesis and aerobic respiration. Comparing Photosynthesis and Aerobic Respiration Photosynthesis Aerobic Respiration Energy stored released Raw materials water and carbon dioxide glucose and oxygen End products glucose and oxygen water and carbon dioxide Where cells with chlorophyll cells with mitochondria Picture This 8. Compare and Contrast Highlight water and carbon dioxide for each process in one color and glucose and oxygen in another color. South Carolina Science Essentials 25 After You Read Mini Glossary chlorophyll (KLOR uh fihl): a green pigment found in chloroplasts photosynthesis (foh toh SIHN thuh suhs): the process during which a plant’s chlorophyll traps light energy and sugars are produced respiration: a series of chemical reactions that breaks down food molecules and releases energy stomata (stoh MAH tah): small openings in the leaf epidermis, which act as doorways for raw materials to enter and exit the leaf 1. Review the terms and their definitions in the Mini Glossary. Write one or two sentences that explain the difference between photosynthesis and respiration. 2. Choose one of the question headings in the Read to Learn section. Write the question in the space below. Then write your answer to that question on the lines that follow. 3. How did your notes help you summarize what you read in this section? End of Lesson 26 Lesson F Photosynthesis and Respiration Visit msscience.com to access your textbook, interactive games, and projects to help you learn more about photosynthesis and respiration. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Write your question here. Llesson 3 G Infectious Diseases Standard 6-2.9: Explain how disease-causing fungi can affect plants. Before You Read How do you think washing hands helps prevent disease? Read to Learn Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Disease in History In the past, there were no treatments for diseases such as the plague, smallpox, and influenza. These diseases killed millions of people worldwide. Today the causes of these diseases are known, and treatments can prevent or cure them. However, some diseases still cannot be cured. Outbreaks of new diseases that have no known cure also occur. What You’ll Learn the work done by scientists to discover and prevent disease ■ diseases caused by viruses and bacteria ■ the causes of sexually transmitted diseases ■ Study Coach Read-and-Say Work with a partner. Read the information under a heading to yourselves. Then discuss together what you learned. Continue until you both understand the main ideas of this lesson. Do microorganisms cause disease? In the late 1700s, the microscope was invented. Under a microscope, scientists were able to see microorganisms such as bacteria, yeast, and mold spores for the first time. By the late 1800s and early 1900s, scientists understood that microorganisms could cause diseases and carry them from one person to another. What did Louis Pasteur discover? The French chemist Louis Pasteur discovered that micro-organisms could spoil wine and milk. He then realized that microorganisms could attack the human body in the same way, causing diseases. Pasteur invented pasteurization (pas chuh ruh ZAY shun), which is the process of heating liquid to a specific temperature that kills most bacteria. 1. Infer What liquids do you drink that you think have undergone pasteurization? South Carolina Science Essentials 27 Which microorganisms cause diseases? Many diseases are caused by bacteria, viruses, protists (PROH tihsts), or fungi. Bacteria can slow the normal growth and activities of body cells and tissues. Some bacteria produce toxins, or poisons, that kill body cells on contact. The table below lists some of the diseases caused by different groups of pathogens. Picture This Identify What type of pathogen causes strep throat? Viruses A virus is a tiny piece of genetic material surrounded by a protein coating that infects host cells and multiplies inside them. The host cells die when the viruses break out of them. These new viruses infect other cells. Viruses destroy tissues or interrupt important body activities. Other Pathogens Protists can destroy tissues and blood cells. They also can interfere with normal body functions. Fungus infections work in a similar way. They can cause skin infections, such as athlete’s foot and ringworm, nonhealing wounds, and chronic lung disease. Many fungi also cause plant diseases. Dutch elm disease, apple scab, smuts, and rusts are plant diseases caused by different types of fungi. The damage to and loss of plant crops because of fungal diseases can cost billions of dollars each year. What did Joseph Lister discover? Organize Make a folded table with three columns and three rows, as shown below. Use the Foldable to record facts about types of diseases. 28 Lesson G Infectious Diseases Today we know that washing hands kills bacteria and other organisms that spread disease. But until the late 1800s, people, including doctors, did not know this. Joseph Lister, an English surgeon, saw that infection and cleanliness were related. Lister learned that carbolic (kar BAH lik) acid kills pathogens. He greatly reduced the number of deaths among his patients by washing their skin, his hands, and his surgical instruments with carbolic acid. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. 2. Pathogens Bacteria Protists Fungi Viruses Human Diseases and the Pathogens that Cause Them Diseases Caused Tetanus, tuberculosis, typhoid fever, strep throat, bacterial pneumonia, plague Malaria, sleeping sickness Athlete’s foot, ringworm Colds, influenza, AIDS, measles, mumps, polio, smallpox What operating procedures are followed today? Today special soaps are used to kill pathogens on skin. Every person who helps perform surgery must wash his or her hands thoroughly and wear sterile gloves and a covering gown. The patient’s skin is cleaned around the area of the body to be operated on and then covered with sterile cloths. Surgery instruments and all operating equipment are sterilized. The air in the operating room is filtered to keep out pathogens. 3. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. How Diseases Are Spread List two operating procedures followed today. An infectious disease is a disease that is spread from an infected organism or the environment to another organism. An infectious disease can be caused by a virus, bacterium, protist, or fungus. Infectious diseases are spread in many ways. They can be spread by direct contact with the infected organism, through water and air, on food, or by contact with contaminated objects. They can also be spread by disease-carrying organisms called biological vectors. Rats, birds, and flies are examples of biological vectors. People also can be carriers of diseases. When you have the flu and sneeze, you send thousands of virus particles into the air. These particles can spread the virus to others. Colds and many other diseases also can be spread by contact. Everything you touch may have disease-causing bacteria or viruses on it. Washing your hands regularly is an important way to avoid disease. Sexually Transmitted Diseases Infectious diseases that are passed from person to person during sexual contact are called sexually transmitted diseases (STDs). STDs are caused by bacteria or viruses. What are bacterial STDs? Explain Use a quarter-sheet of notebook paper to define, list the types of, and explain STDs. STDs STDs caused by bacteria are gonorrhea (gah nuh REE uh), chlamydia (kluh MIH dee uh), and syphilis (SIH fuh lus). The symptoms for gonorrhea and chlamydia may not appear right away, so a person may not know that he or she is infected. The symptoms for these STDs are pain when urinating, genital discharge, and genital sores. Bacterial STDs can be treated with antibiotics. If left untreated, gonorrhea and chlamydia can damage the reproductive system, leaving the person unable to have children. South Carolina Science Essentials 29 What are the symptoms for syphilis? 4. Determine At which stage does syphilis cause permanent damage? Syphilis has three stages. In stage 1, a sore that lasts 10 to 14 days appears on the mouth or sex organ. Stage 2 may involve a rash, fever, and swollen lymph glands. In stage 3, syphilis may infect the cardiovascular and nervous systems. Syphilis can be treated with antibiotics in all stages. However damage to body organs in stage 3 cannot be reversed and may lead to death. What is genital herpes? Genital herpes is a lifelong STD caused by a virus. The symptoms include painful blisters on the sex organs. Genital herpes can be passed from one person to another during sexual contact or from an infected mother to her child during birth. The herpes virus hides in the body for long periods of time without causing symptoms and then reappears suddenly. The symptoms for genital herpes can be treated with medicine, but there is no cure or vaccine for the disease. Human immunodeficiency virus (HIV) can exist in blood and body fluids. This virus can hide in body cells, sometimes for years. HIV can be passed on by an infected person through sexual contact. A person can also be infected by reusing an HIV-contaminated needle for an injection. A sterile needle, however, cannot pass on HIV. The risk of getting HIV through blood transfusion is small because all donated blood is tested for HIV. An HIV-infected pregnant woman can infect her unborn child. A baby can get HIV after birth when nursing from an HIV-infected mother. 5. Identify What are two ways that a teenager or adult can get HIV? 30 Lesson G Infectious Diseases What is AIDS? An HIV infection can lead to Acquired Immune Deficiency Syndrome (AIDS). AIDS is a disease that attacks the body’s immune system. HIV is different from other viruses. It attacks the helper T cells in the immune system. HIV enters the T cell and multiples. When the infected T cell bursts open, it releases more HIV that infects more T cells. Soon, so many T cells are destroyed that not enough B cells are formed to produce antibodies. Once HIV has reached this stage, the infected person has AIDS. The immune system can no longer fight HIV or any other pathogen. There is no cure for AIDS, but several kinds of medicines help treat AIDS in some patients. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. HIV and Your Immune System Fighting Disease The first step to preventing infections is to wash small wounds with soap and water. Cleaning the wound with an antiseptic and covering it with a bandage also help fight infection. Washing your hands and body helps prevent body odor. Washing also removes and destroys microorganisms on your skin. Health-care workers, such as the one shown below, wash their hands between patients. This reduces the spread of pathogens from one person to another. Picture This 6. Identify other types of Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. jobs where workers should wash their hands often. Mark Burnett Microorganisms in your mouth cause mouth odor and tooth decay. Brushing and flossing your teeth every day keep these microorganisms under control. Exercising, eating healthy foods, and getting plenty of rest help keep you healthy. You are less likely to get a cold or the flu if you have good health habits. Having checkups every year and getting the recommended vaccinations also help you stay healthy. 7. Apply List two things you do every day to keep healthy. South Carolina Science Essentials 31 After You Read Mini Glossary biological vector: a disease-carrying organism infectious disease: a disease that is caused by a virus, bacterium, protist, or fungus and is spread by an organism or the environment to another organism pasteurization (pas chuh ruh ZAY shun): the process of heating a liquid to a specific temperature that kills most bacteria sexually transmitted disease (STD): an infectious disease that is passed from person to person during sexual contact virus: a small piece of genetic material surrounded by a protein coating that infects and multiplies in host cells 1. Review the terms and their definitions in the Mini Glossary. Choose one term that identifies a way a person gets a disease. Write a sentence about how the term you selected causes infection. 2. Complete the table below to identify the causes, symptoms, and treatments of STDs. Causes (Bacteria or Virus) Symptoms Treatment Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Kinds of STDs Gonorrhea Chlamydia Syphilis Genital herpes Visit msscience.com to access your textbook, interactive games, and projects to help you learn more about infectious diseases. 32 Lesson G Infectious Diseases End of Lesson Llesson 3 H What is an animal? Standard 6-3.1: Compare the characteristic structures of invertebrate animals (including sponges, segmented worms, echinoderms, mollusks, and arthropods) and vertebrate animals (fish, amphibians, reptiles, birds, and mammals). Before You Read What You’ll Learn the characteristics of animals ■ the differences between vertebrates and invertebrates ■ List the names of five animals on the lines below. Then write one thing that these animals have in common. Read to Learn Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Animal Characteristics If you asked ten people what all animals have in common, you would get many different answers. Animals come in many different shapes and sizes. All animals, however, have five common characteristics. 1. All animals are many-celled organisms that are made of different kinds of cells. 2. Most animal cells have a nucleus and organelles. The nucleus and many of the organelles are surrounded by a membrane. A cell that contains a nucleus and organelles surrounded by membranes is called a eukaryotic (yew ker ee AH tihk) cell. 3. Animals cannot make their own food. 4. Animals digest their food. 5. Most animals can move from place to place. What is symmetry? As you study different groups of animals, you will look at their symmetry (SIH muh tree). Symmetry refers to the way parts of an object are arranged. If the parts are arranged in a way that allows the object to be divided into similar halves, it is symmetrical. Study Coach Quiz Yourself As you read the lesson, write a question for each paragraph. Answer the question with information from the paragraph. Use the questions and answers to study the lesson. 1. Analyze Name one reason animals need to move from place to place. South Carolina Science Essentials 33 What kind of symmetry do most animals have? Explain What two forms of symmetry do most animals have? Sea anemones have radial symmetry. Picture This 3. Classify Draw a simple human figure beside the type of symmetry that humans have. 34 Lesson H What is an animal? Lobsters have bilateral symmetry. Many sponges are asymmetrical. What is an asymmetrical animal like? An animal with an uneven shape is called asymmetrical (AY suh meh trih kul). Its body cannot be divided into halves that are similar. Look at the sponge in the figure above. Notice that you cannot draw a line down the center of its body to divide it into two halves that are similar. As you learn more about invertebrates, think about their body symmetry. Notice how body symmetry affects the way they gather food and do other things. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. 2. Most animals have either radial symmetry or bilateral symmetry. An animal with body parts arranged in a circle around a central point has radial symmetry. As you can see in the figure below, a sea anemone has radial symmetry. An animal with radial symmetry can find food and gather information from all directions. Other animals that have radial symmetry are jellyfish and sea urchins. An animal with bilateral symmetry has parts that are nearly mirror images of each other. You can draw a line down the center of its body to divide it into two similar parts. The figure below shows that a lobster has bilateral symmetry. A human also has bilateral symmetry. Animal Classification Applying Math Animals have many characteristics in common. But when you think about the variety of animals you can name, you know that there are many different kinds of animals. Some animals have legs, others have wings. Some live on land, others live in water. Scientists use a classification system to place all animals into related groups. Scientists separate animals into two groups—vertebrates (VUR tuh bruts) and invertebrates (ihn VUR tuh bruts). These two groups are shown in the figure below. Vertebrates are animals that have a backbone. Invertebrates are animals that do not have a backbone. About 97 percent of all animals are invertebrates. 4. Create a Circle Graph In the circle below, draw a circle graph showing the percent of invertebrates and the percent of vertebrates. Animal Kingdom Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Invertebrates Vertebrates Scientists further classify the invertebrates into smaller groups, as shown in the figure below. The animals in each group share similar characteristics. These characteristics show that the animals within the group may have had a common ancestor. Picture This Invertebrates 5. Cnidarians Sponges Roundworms Flatworms Mollusks Annelids Echinoderms Identify Circle any words in the diagram that you do not know. When you have finished reading this lesson, review the words you circled and state a characteristic of each one. Arthropods South Carolina Science Essentials 35 After You Read Mini Glossary invertebrates (ihn VUR tuh bruts): animals that do not have a backbone symmetry (SIH muh tree): the way parts of an object are arranged 1. Review the terms and their definitions in the Mini Glossary. Write a sentence that explains the difference between an animal that has symmetry and one that is asymmetrical. 2. Fill in the table below to describe the common characteristics of all animals. Common Characteristics of All Animals 1. 3. 4. 5. 3. How did writing and answering quiz questions help you remember what you have read about animal characteristics and classification? End of Lesson 36 Lesson H What is an animal? Visit msscience.com to access your textbook, interactive games, and projects to help you learn more about the characteristics of animals. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. 2. Llesson 3I Sponges, Cnidarians, Flatworms, and Roundworms Standard 6-3.1: Compare the characteristic structures of invertebrate animals (including sponges, segmented worms, echinoderms, mollusks, and arthropods) and vertebrate animals (fish, amphibians, reptiles, birds, and mammals). Standard 6-3.2: Summarize the basic functions of the structures of animals that allow them to defend themselves, to move, and to obtain resources. Before You Read What You’ll Learn the structures of sponges and cnidarians ■ how sponges and cnidarians get food and reproduce ■ about flatworms and roundworms ■ On the lines below, list a difference between the way plants and animals get food. Read to Learn Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Sponges Sponges are classified as animals because they cannot make their own food. A sponge’s body is made of two layers of cells. Adult sponges remain attached to one place for their lifetime. There are about 15,000 species of sponges. Study Coach Sticky-Note Discussions As you read the lesson, use sticky-note paper to mark paragraphs you find interesting. Share the interesting information with a partner. How does a sponge eat? All sponges are filter feeders. Sponges filter tiny food particles from the water that flows through their bodies. The inner part of a sponge’s body is lined with collar cells. Thin, whiplike structures, called flagella (flah JEH luh), are attached to the collar cells. The whiplike movements of the flagella keep water moving through the sponge. Other cells digest the food, carry nutrients to all parts of the sponge, and remove wastes. Explain Make a four-tab book Foldable, as shown below. Take notes on what you read about each classification of animal. How does a sponge protect itself? Many sponges have soft bodies that are supported by sharp, glass-like structures called spicules (SPIHK yewlz). Other sponges contain a substance called spongin, which is like foam rubber. Spongin makes sponges soft and stretchable. Some sponges have both spicules and spongin to protect their soft bodies. Sponges Cnidarians Flatworms Roundworms South Carolina Science Essentials 37 How do sponges reproduce? Sponges can reproduce asexually and sexually. A sponge reproduces asexually when a bud on the side of the parent sponge develops into a small sponge. The small sponge breaks off, floats away, and attaches itself to a new surface. New sponges also can grow from pieces of a sponge. Most sponges that reproduce sexually are hermaphrodites (hur MA fruh dites). This means they produce both eggs and sperm. The figure below shows sexual reproduction in sponges. Sponges release sperm into the water. The sperm float until they are drawn into another sponge. The sperm fertilizes an egg. A larva develops in the sponge. The larva leaves the sponge and settles to the bottom. It attaches to the surface on which it lands and grows into a new sponge. Picture This 1. Identify Circle the names of two structures needed for sexual reproduction. Flagella Larvae New sponge Cnidarians 2. Explain Why does a cnidarian use stinging cells? 38 Jellyfish, sea anemones, hydra, and corals are cnidarians. Cnidarians (nih DAR ee unz) are hollowed-bodied animals with two cell layers that are organized into tissues. Cnidarians have tentacles surrounding their mouths. The tentacles shoot out harpoon-like stinging cells to capture prey. Cnidarians have radial symmetry, so they can locate food that floats by from any direction. The inner cell layer digests the food. Nerve cells work together as a nerve net throughout the whole body. Lesson I Sponges, Cnidarians, Flatworms, and Roundworms Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Sperm cells Egg cell What kinds of body forms do cnidarians have? Cnidarians have two different body forms. The vase-shaped body form is called a polyp (PAH lup). Sea anemones and hydras are polyps. Polyps usually remain attached to a surface. A jellyfish has a free-swimming, bell-shaped body that is called a medusa (mih DEW suh). Jellyfish are not strong swimmers. Instead they drift with the ocean currents. Some cnidarians go through both a polyp stage and a medusa stage during their life cycles. 3. Identify the two body forms of cnidarians. How do cnidarians reproduce? Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Cnidarians reproduce both sexually and asexually. The polyp form of a cnidarian reproduces asexually by budding. The bud falls off the parent and develops into a new polyp. Some polyps also can reproduce sexually by releasing eggs or sperm into the water. Eggs that are fertilized by the sperm develop into new polyps. The medusa form of a cnidarian has a two-stage life cycle, as shown in the figure below. A medusa reproduces sexually to produce polyps. Then each polyp reproduces asexually to form new medusae. Picture This 4. Apply Draw a circle around the three pictures of the medusae in the diagram. Medusae Female Male Sperm Egg Asexual reproduction The young medusae bud off the polyp, and the cycle begins again. In the sexual stage, the free-swimming female medusa releases eggs and the male medusa releases sperm. In the asexual stage, the polyp grows and forms buds that become tiny medusae. Sexual reproduction A larva develops and attaches to rocks or other surfaces. Larva Polyp South Carolina Science Essentials 39 Flatworms 5. Explain how a tapeworm attaches to the host’s intestine. Unlike sponges and cnidarians, flatworms search for food. Flatworms are invertebrates with long, flattened bodies and bilateral symmetry. A flatworm’s body is soft and has three layers of tissue organized into organs and organ systems. Some kinds of flatworms can move around and search for food. These flatworms have a digestive system with one opening. Most flatworms are parasites that live in or on their hosts. A parasite gets its food and shelter from its host. What are tapeworms? Tapeworms are flatworms that live in the intestines of their hosts. A tapeworm does not have a digestive system. It gets its nutrients from digested food in the host’s intestine. A tapeworm’s head has hooks and suckers that attach to the host’s intestine. A human can be a host for a tapeworm. The body of a tapeworm is made up of segments. A tapeworm grows by adding segments directly behind its head. Each body section has both male and female reproductive organs. Eggs and sperm are released inside the segment. After it is filled with fertilized eggs, the segment breaks off. The segment passes with wastes out of the host’s body. If it is eaten by another host, the fertilized egg hatches and develops into a tapeworm. Roundworms 6. Determine What is the host for a heartworm? 40 Roundworms are the most widespread animal on Earth. There are thousands of kinds of roundworms. Heartworms, which can infect the hearts of dogs, are one kind of roundworm. A roundworm’s body is a tube inside a tube. Between the two tubes is a cavity full of fluid. The fluid-filled cavity separates the digestive tract from the body wall. The digestive tract of a roundworm has two openings. Food enters the roundworm through the mouth, is digested in a digestive tract, and wastes exit through the anus. Some roundworms are decomposers. Other roundworms are predators. The heartworm is a roundworm that is an animal parasite. Some roundworms are plant parasites. Lesson I Sponges, Cnidarians, Flatworms, and Roundworms Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. How do tapeworms reproduce? After You Read Mini Glossary cnidarian (nih DAR ee un): a hollow-bodied animal with tentacles for catching food and two cell layers that are organized into tissues medusa (mih DEW suh): a free-swimming, bell-shaped body of a cnidarian polyp (PAH lup): a vase-shaped body of a cnidarian 1. Review the terms and their definitions in the Mini Glossary. Choose the term that names an invertebrate. Write a sentence describing the animal. 2. Complete the Venn diagram below to help you compare flatworms and roundworms. Roundworms Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Flatworms Visit msscience.com to access your textbook, interactive games, and projects to help you learn more about sponges, cnidarians, flatworms, and roundworms. End of Lesson South Carolina Science Essentials 41 Llesson 3J Mollusks and Segmented Worms Standard 6-3.1: Compare the characteristic structures of invertebrate animals (including sponges, segmented worms, echinoderms, mollusks, and arthropods) and vertebrate animals (fish, amphibians, reptiles, birds, and mammals). Standard 6-3.2: Summarize the basic functions of the structures of animals that allow them to defend themselves, to move, and to obtain resources. Before You Read What You’ll Learn On the lines below, describe some characteristics of an earthworm. Read to Learn Identify Main Ideas Highlight the main idea in each paragraph. Review the main ideas after you have finished reading. Mollusks A mollusk is a soft-bodied invertebrate that usually has a shell. A mollusk also has a mantle and a large, muscular foot. The mantle is a thin layer of tissue that covers the mollusk’s soft body. The foot is used for moving or for holding the animal in one place. Snails, mussels, and octopuses are mollusks. Mollusks that live in water have gills. Gills are organs in which carbon dioxide from the animal is exchanged for oxygen from the water. Mollusks that live on land have lungs in which carbon dioxide from the animal is exchanged for oxygen from the air. What body systems does a mollusk have? 1. Define What is a radula? 42 A mollusk has a digestive system with two openings. Many mollusks have a scratchy tonguelike organ called the radula (RA juh luh). The radula has rows of tiny, sharp teeth that the mollusk uses to scrape small bits of food off rocks and other surfaces. Some mollusks have an open circulatory system, which means they do not have blood vessels. Instead, the blood washes over the organs, which are grouped together in a fluid-filled cavity inside the animal’s body. Lesson J Mollusks and Segmented Worms Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. the characteristics of mollusks ■ differences between an open and a closed circulatory system ■ the characteristics of segmented worms ■ the digestive process of an earthworm ■ Types of Mollusks Scientists use three characteristics to classify a mollusk. 1. Does the mollusk have a shell? 2. If the mollusk has a shell, what kind of shell is it? 3. What type of foot does the mollusk have? What are gastropods? Gastropods are the largest group of mollusks. Most gastropods have one shell. Snails and conchs are examples of single-shelled gastropods. A slug is a gastropod that has no shell. Some gastropods live in water and others live on land. A gastropod uses its large, muscular foot to move about. Gastropods secrete mucus, which helps them glide across surfaces. Describe Make a six-tab book Foldable, as shown below. Write the main ideas as you read about each type of mollusk or segmented worm. s opod Gastr s Bivalve What are bivalves? pods Cephalo Bivalves are mollusks with two shell halves joined by a hinge. Scallops and clams are bivalves. Large, powerful muscles open and close the shell halves. Bivalves are water animals. A bivalve filters food from water that enters into and is filtered through the gills. ms Earthwor Leeches orms Marine W Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. What are cephalopods? Squid and octopuses are cephalopods (SE fah lah pawdz). Most cephalopods have a stiff plate inside their bodies instead of a shell on the outside. They have a well-developed head and a “foot” that is made up of tentacles with suckers. The mouth is at the base of the tentacles. A cephalopod has a closed circulatory system in which blood is carried through blood vessels. Cephalopods can move quickly through the water. The figure below compares the movement of a squid as it releases water to the movement of a balloon as it releases air. Direction of balloon Picture This 2. Air in Explain Use the figure to explain to a partner how a squid moves. Air out Direction of squid Water in Water out South Carolina Science Essentials 43 How does a cephalopod move? A muscular envelope, called the mantle, surrounds a cephalopod’s internal organs. Water enters the space between the mantle and the body organs. When the mantle closes, water is squeezed through a funnel-like structure called a siphon. This squeezing creates a force that causes the animal to move in the opposite direction of the stream of water. Segmented Worms Earthworms, leeches, and marine worms are segmented worms. Segmented worms are also called annelids (A nul idz). A segmented worm’s body is made up of repeating rings that make the worm flexible. Each ring or segment has nerve cells, blood vessels, part of the digestive tract, and the coelom (SEE lum). The coelom is a body cavity that separates the internal organs from the inside of the body wall. A segmented worm has a closed circulatory system and a complete digestive system with two body openings. Describe What separates the internal organs of an earthworm from the body wall? How does an earthworm move and eat? An earthworm has more than 100 rings or segments. Each segment has bristles, or setae (SEE tee), on the outside. Setae are used to grip the soil while two sets of muscles move them through the soil. As the earthworm moves, it takes soil into its mouth. The earthworm gets its food from the soil. The soil moves from the mouth, to the crop, to the gizzard. In the gizzard, the food and the soil are ground. In the intestine, the food is broken down and absorbed by the blood. Waste materials and undigested soil leave the earthworm through the anus. All of these structures are shown in the figure below. Mouth Brain Hearts Blood vessels Crop Picture This 4. Reproductive structures Main nerve cord Intestine Waste removal tubes Gizzard Identify Circle the parts of an earthworm that are also found in humans. 44 Lesson J Mollusks and Segmented Worms Anus Setae Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. 3. How does an earthworm breathe? An earthworm does not have lungs or gills. An earthworm breathes through its mucous-covered skin. Carbon dioxide moves out of the body and oxygen moves into the body through the skin. If the mucus covering the skin is removed, the earthworm may die of suffocation. How does a leech get its food? 5. Explain how an earthworm breathes. 6. Apply How do marine worms use setae? Leeches can be found in freshwater, salt or marine water, and on land. A leech is a segmented worm with a flat body. It has suckers on both ends that it uses to attach itself to an animal to remove blood. A leech can store large amounts of blood that it slowly releases into its digestive system when it needs food. Some leeches can store as much as ten times their own weight in blood, and the blood can be stored for months. Although leeches like a diet of blood, most can eat small water animals. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. What are the characteristics of a marine worm? There are more than 8,000 kinds of marine worms. Marine worms are the most varied group of annelids. The word polychaete means “many bristles.” A marine worm has bristles, or setae, along the sides of its body. Because of these bristles, marine worms are sometimes called bristle worms. Marine worms can use these setae to walk, swim, or dig. Some marine worms are filter feeders. They either dig down into the mud or build hollow tubes. Then they use their bristles to filter food from the water. Others eat plants or decaying materials. Some marine worms are predators and some are parasites. The many ways that marine worms get food explains why they are so varied. South Carolina Science Essentials 45 After You Read Mini Glossary closed circulatory system: a circulatory system in which blood is carried through blood vessels gill: an organ in which carbon dioxide from an animal is exchanged for oxygen from the water mantle: a thin layer of tissue that covers a mollusk’s soft body mollusk: a soft-bodied invertebrate that has a mantle and a large muscular foot; usually has a shell open circulatory system: a circulatory system without blood vessels in which blood washes over the organs radula (RA juh luh): a tonguelike organ in mollusks 1. Review the terms and their definitions in the Mini Glossary. Write two sentences that explain the difference between an open circulatory system and a closed circulatory system. 2. Fill in the table below to identify the main characteristics of mollusks and segmented worms. Main Characteristics Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. 1. 2. Mollusks 3. 4. 5. 6. 1. Segmented Worms 2. 3. 4. End of Lesson 46 Lesson J Mollusks and Segmented Worms Visit msscience.com to access your textbook, interactive games, and projects to help you learn more about mollusks and segmented worms. Llesson 3 K Arthropods and Echinoderms Standard 6-3.1: Compare the characteristic structures of invertebrate animals (including sponges, segmented worms, echinoderms, mollusks, and arthropods) and vertebrate animals (fish, amphibians, reptiles, birds, and mammals). Standard 6-3.2: Summarize the basic functions of the structures of animals that allow them to defend themselves, to move, and to obtain resources. Standard 6-3.4: Explain how environmental stimuli cause physical responses in animals (including shedding, blinking, shivering, sweating, panting, and food gathering). Standard 6.3.5: Illustrate animal behavioral responses (including hibernation, migration, defense, and courtship) to environmental stimuli. Standard 6-3.6: Summarize how the internal stimuli (including hunger, thirst, and sleep) of animals ensure their survival. Before You Read What You’ll Learn the features used to classify arthropods ■ the structure and function of the exoskeleton ■ the features of echinoderms ■ On the lines below, list three kinds of insects. Next to the name of each insect, write a short description of the insect. Read to Learn Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Arthropods An arthropod (AR thruh pahd) is an invertebrate animal with jointed appendages (uh PEN dih juz). Appendages are structures such as claws, legs, or antennae that grow from the body. Arthropods have bilateral symmetry and segmented bodies. Study Coach Summarize As you read this lesson, stop after every paragraph and summarize what you have just read in your own words. How does an arthropod protect itself? Arthropods have hard body coverings called exoskeletons. The exoskeleton protects and supports the animal’s body and reduces water loss. As the animal grows, the old exoskeleton must be shed because it does not grow with the animal. The process of shedding the exoskeleton is called molting. What are the characteristics of insects? Insects make up the largest group of arthropods. Scientists have classified more than 700,000 species of insects. Insects have three body regions—head, thorax, and abdomen. Insects have an open circulatory system. Many insects, such as butterflies, completely change their body form as they grow. This change in body form is called metamorphosis (met uh MOR fuh sus). Compare Make a two-tab book Foldable, as shown below. Write statements or phrases about Arthropods and Echinoderms as you read. Use the statements to compare these animals. Arthropods Echinoderms South Carolina Science Essentials 47 What are two kinds of metamorphosis? There are two kinds of insect metamorphosis—complete and incomplete. Complete metamorphosis is shown on the left in the figure below. It has four stages—egg, larva, pupa (PYEW puh), and adult. Notice that each stage is different from the others. The three stages of incomplete metamorphosis—egg, nymph, and adult—are shown on the right in the figure below. A nymph looks like a small adult. Complete Metamorphosis Incomplete Metamorphosis Nymph Eggs Molt Nymph Adult Egg Picture This 1. Identify Circle the names of the stages that are the same for complete and incomplete metamorphosis. Molt Pupa Larva Adult Arachnids (uh RAK nudz) are arthropods that have only two body regions—a cephalothorax (sef uh luh THOR aks) and an abdomen. The cephalothorax is a body region made up of a head and a thorax. An arachnid has four pairs of legs attached to its cephalothorax. Spiders, ticks, mites, and scorpions are arachnids. How do spiders catch their food? Applying Math 2. Spiders are predators that use a pair of appendages near their mouths to inject venom, or poison, into their prey. The venom makes the prey unable to move. After the prey has been injected with venom, spiders inject another substance that turns the prey’s body into a liquid, which spiders drink. Some spiders weave webs to trap their prey. Other spiders chase and catch their prey. Calculate Complete the What are centipedes and millipedes? following sentence by filling in the correct numbers. A centipede with 30 segments has ______ legs. A millipede with 30 segments has ______ legs. Centipedes and millipedes are long, thin segmented animals. Centipedes have one pair of jointed legs attached to each segment. They are predators that use poison to catch prey. Millipedes have two pairs of jointed legs attached to each segment. They eat plants. 48 Lesson K Arthropods and Echinoderms Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. What is an arachnid? What are the characteristics of crustaceans? Crustaceans include some of the largest arthropods, such as crabs and lobsters. Most crustaceans are small marine animals called zooplankton. Zooplankton are tiny free-floating animals that serve as food for other marine animals. Most crustaceans have two pairs of antennae attached to the head, three types of chewing appendages, and five pairs of legs. Many crustaceans that live in water also have appendages called swimmerets on the abdomen. Swimmerets help exchange carbon dioxide from the animal for oxygen in the water. 3. Determine What is the purpose of swimmerets? Echinoderms Echinoderms (ih KI nuh durmz) are animals that have radial symmetry. Sea stars and sand dollars are echinoderms. Echinoderms have spines of different lengths that cover the outside of their bodies. Most echinoderms have an internal skeleton made up of bonelike plates that supports and protects the animal. Echinoderms have a simple nervous system, but no head or brain. Some echinoderms are predators, some are filter feeders, and some feed on decaying matter. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. What is a water-vascular system? An echinoderm has a water-vascular system, which is a network of water-filled canals and thousands of tube feet. The tube feet work like suction cups to help the animal move and capture prey. The figure below shows the parts of a sea star. A sea star eats by pushing its stomach out of its mouth and into the opened shell of its prey. After the prey’s body is digested, the sea star pulls in its stomach. Like some other invertebrates, sea stars can regrow lost or damaged parts. Picture This Anus 4. Ray Explain Use the diagram to explain to a partner how the sea star eats. Stomach Mouth Radial canal Tube feet South Carolina Science Essentials 49 After You Read Mini Glossary appendage (uh PEN dihj): a structure such as a claw, leg, or antennae that grows from the body arthropod (AR thruh pahd): an invertebrate animal with jointed appendages and an exoskeleton exoskeleton: a hard body covering that protects and supports the body and reduces water loss metamorphosis (met uh MOR fuh sus): a change in body form 1. Review the terms and their definitions in the Mini Glossary. Write a sentence that describes how an arthropod might use an appendage. 2. Complete the concept map below about arthropod classification. Body Regions Arachnids 1. 1. 2. 2. 3. 3. Complete the flowcharts to compare complete and incomplete metamorphosis. Complete Metamorphosis 1. 2. 3. 4. Incomplete Metamorphosis 1. 2. End of Lesson 50 Lesson K Arthropods and Echinoderms 3. Visit msscience.com to access your textbook, interactive games, and projects to help you learn more about arthropods and echinoderms. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Insects Llesson L3 Chordate Animals Standard 6-3.1: Compare the characteristic structures of invertebrate animals (including sponges, segmented worms, echinoderms, mollusks, and arthropods) and vertebrate animals (fish, amphibians, reptiles, birds, and mammals). Standard 6-3.2: Summarize the basic functions of the structures of animals that allow them to defend themselves, to move, and to obtain resources. Standard 6-3.3: Compare the response that a warm-blooded (endothermic) animal makes to a fluctuation in environmental temperature with the response that a cold-blooded (ectothermic) animal makes to such a fluctuation. Standard 6-3.4: Explain how environmental stimuli cause physical responses in animals (including shedding, blinking, shivering, sweating, panting, and food gathering). Standard 6.3.5: Illustrate animal behavioral responses (including hibernation, migration, defense, and courtship) to environmental stimuli. Before You Read What You’ll Learn List three animals on the lines below. Then write one thing that all these animals have in common with humans. Read to Learn Study Coach Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. What is a chordate? Chordates (KOR dayts) are animals that have the following three characteristics—a notochord (NOH tuh cord), a nerve cord, and pharyngeal (fur RIN jee uhl) pouches at some time during their development. The notochord is a flexible rod that runs the length of the developing organism. The nerve cord is made of nerve tissue. In most chordates, one end of the nerve cord develops into the organism’s brain. Pharyngeal pouches are slitlike openings between the inside of the body and the outside of the body. They are present only in the early stages of the organism’s development. In some chordates, like the lancelet in the figure below, the pharyngeal pouches develop into gill slits. Nerve cord the characteristics of chordates ■ the characteristics of all vertebrates ■ the difference between ectotherms and endotherms ■ the three classes of fish ■ Gill slits Notochord Movement of water Create a Quiz Write a question about the main idea under each heading. Exchange quizzes with another student. Together discuss the answers to the quiz questions. Define Use a quarter sheet of notebook paper, as shown below, to define the key words in this lesson—chordate, ectotherm, endotherm, and cartilage. Chordate Ectotherm Endotherm Cartilage South Carolina Science Essentials 51 What are the characteristics of vertebrates? Chordates are classified into several smaller groups. The largest group of chordates is made up of the vertebrates, which include humans. All vertebrates have an internal system of bones called an endoskeleton. The endoskeleton supports and protects the body’s internal organs. For example, the skull is the part of the endoskeleton that surrounds and protects the brain. How do vertebrates control body temperature? Identify Make a two-tab Foldable, as shown below. Identify the characteristics of ectotherms and endotherms. Ectotherms Endotherms Vertebrates are either ectotherms or endotherms. Ectotherms (EK tuh thurmz) are cold-blooded animals. Their body temperature changes as the temperature of their surroundings changes. Fish are ectotherms. Endotherms (EN duh thurmz) are warm-blooded animals. Their body temperature does not change with the surrounding temperature. Humans are endotherms. Your body temperature is usually about 37°C. 1. Explain the purpose of fish gills. Fish are the largest group of vertebrates. All fish are ectotherms and live in water. Some species of fish are adapted to live in freshwater and other species are adapted to live in salt water. Fish have gills. Gills are fleshy filaments where carbon dioxide and oxygen are exchanged. Water that contains oxygen passes over the gills. When blood is pumped into the gills, the oxygen in the water moves into the blood. At the same time, carbon dioxide moves out of the blood in the gills and into the water. Most fish have pairs of fanlike fins. Fish use fins to steer, balance, and move. The motion of the tail fin pushes the fish through the water. Most fish have scales. Scales are thin structures made of a bony material that overlap to cover the skin. Types of Fish Scientists classify fish into three groups—bony, jawless, and cartilaginous (kar tuh LA juh nuhs). Bony fish have endoskeletons made of bone. Jawless fish and cartilaginous fish have endoskeletons made of cartilage. Cartilage (KAR tuh lihj) is a tough, flexible tissue that is similar to bone but is not as hard or as easily broken. 52 Lesson L Chordate Animals Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Fish What are the characteristics of bony fish? About 95 percent of all fish species are bony fish. Goldfish, trout, and marlins are examples. The body structure of a bony fish is shown in the figure below. Bony fish swim easily in water because their scales are covered with slimy mucus. Bony vertebra Picture This Swim bladder Brain 2. Highlight In the drawing of a bony fish, color the skeleton of the fish and label it Skeleton. 3. Determine How does external fertilization take place? Nostril Scales Mouth Intestine Stomach Liver Gills Heart Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Most bony fish have a swim bladder. A swim bladder is an air sac that helps control the depth at which the fish swims. Gases move between the swim bladder and the fish’s blood. When gases move into the swim bladder, the fish rises in the water. When gases leave the swim bladder, the fish sinks lower in the water. How do bony fish reproduce? Most bony fish reproduce using external fertilization (fur tuh luh ZAY shun). External fertilization takes place when egg and sperm cells join outside the female’s body. First, a female releases large numbers of eggs into the water. Then, a male swims over the eggs, releasing sperm into the water. Many eggs are fertilized by the sperm. What are jawless and cartilaginous fish? Jawless fish have long, tubelike bodies with no scales. They have round, muscular mouths with no jaw. Their mouths have sharp toothlike structures. Their endoskeleton is made of cartilage. Lampreys are jawless fish that attach to another fish with their strong mouths. Lampreys feed by removing blood and other body fluids from the host fish. Cartilaginous fish also have endoskeletons made of cartilage. They have movable jaws that usually have well-developed teeth. Their bodies are covered with sandpaperlike scales. Sharks, skates, and rays are cartilaginous fish. Most cartilaginous fish are predators. South Carolina Science Essentials 53 After You Read Mini Glossary cartilage (KAR tuh lihj): a tough, flexible tissue that is similar to bone, but not as hard or as easily broken chordate (KOR dayt): an animal that has three characteristics present at some time during its development—a notochord, nerve cord, and pharyngeal pouches ectotherm (EK tuh thurm): a cold-blooded animal whose body temperature changes as the temperature of its surroundings changes endotherm (EN duh thurm): a warm-blooded animal whose body temperature does not change with the temperature of its surroundings 1. Review the terms and their definitions in the Mini Glossary. Write a sentence that explains the difference between an ectotherm and an endotherm. 2. Complete the concept map below to show the three classes of fish. 3. How does working with a partner to ask and answer quiz questions prepare you for a test that covers the material you have read? End of Lesson 54 Lesson L Chordate Animals Visit msscience.com to access your textbook, interactive games, and projects to help you learn more about chordate animals. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Fish Llesson 3 M Amphibians and Reptiles Standard 6-3.1: Compare the characteristic structures of invertebrate animals (including sponges, segmented worms, echinoderms, mollusks, and arthropods) and vertebrate animals (fish, amphibians, reptiles, birds, and mammals). Standard 6-3.2: Summarize the basic functions of the structures of animals that allow them to defend themselves, to move, and to obtain resources. Standard 6-3.3: Compare the response that a warm-blooded (endothermic) animal makes to a fluctuation in environmental temperature with the response that a cold-blooded (ectothermic) animal makes to such a fluctuation. Standard 6-3.4: Explain how environmental stimuli cause physical responses in animals (including shedding, blinking, shivering, sweating, panting, and food gathering). Before You Read On the lines below, write four characteristics of frogs and lizards. Read to Learn Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Amphibians Amphibians (am FIH bee unz) are animals that spend part of their lives in water and part on land. They have many adaptations that allow for life both on land and in the water. Amphibians include frogs, toads, salamanders, and newts. How do amphibians adjust when the temperature changes? Amphibians are ectotherms. Their body temperature changes along with changes in the temperature of their environment. In cold weather, amphibians become inactive. They bury themselves in mud or leaves until the temperature warms. This time of inactivity during cold weather is called hibernation. Amphibians that live in hot, dry climates become inactive and hide in the ground when the temperature becomes too hot. This time of inactivity during hot temperatures is called estivation (es tuh VAY shun). What You’ll Learn how amphibians have adapted to live in water and on land ■ what happens during frog metamorphosis ■ the adaptations that allow reptiles to live on land ■ Study Coach K-W-L Chart Fold a sheet of paper into three columns. In the first column, write what you know about amphibians and reptiles. In the second column, write what you want to know about amphibians and reptiles. Then read the lesson. In the third column, write what you learned about amphibians and reptiles from reading the lesson. Define Use a quarter-sheet of notebook paper, as shown below, to define the key words in this lesson—hibernation, estivation, and amniotic egg. What is the body structure of amphibians? Amphibians are vertebrates with a strong endoskeleton made of bones. The skeleton helps support their body while on land. Adult frogs and toads have strong hind legs that they use for swimming and jumping. Hibernation Estivation Amniotic egg South Carolina Science Essentials 55 How do amphibians live on land? 1. Adult amphibians use lungs instead of gills to exchange oxygen and carbon dioxide. Lungs are an important adaptation for living on land. Amphibians have three-chambered hearts, in which blood carrying oxygen mixes with blood carrying carbon dioxide. This mixing makes less oxygen available to the amphibian. Adult amphibians also exchange oxygen and carbon dioxide through their moist skin, which increases their oxygen supply. Amphibians can live on land, but they must stay moist for the exchange of oxygen and carbon dioxide to occur. Amphibian hearing and vision also are adapted to life on land. Amphibians have tympanums (TIHM puh nuhmz), or eardrums, that vibrate in response to sound waves. Large eyes help some amphibians catch their prey. Land environments provide many insects as food for adult amphibians. They have long, sticky tongues used to capture the insects. Describe two characteristics that allow amphibians to live on land. Most amphibians go through a series of body changes called metamorphosis (me tuh MOR fuh sus). Eggs are most often laid in water and hatch into larvae. Young larval forms of amphibians live in water. They have no legs and breathe through gills. Over time, they develop the body structures needed for life on land, including legs and lungs. The rate of metamorphosis depends on the species, the water temperature, and the amount of available food. The figure below shows the stages of development for one amphibian—the frog. Picture This 2. Compare Circle the stage of metamorphosis in which frogs are most like fish. Stage 2: Fertilized frog eggs are hatched into tadpoles. Tadpoles live in water. They use their gills for gas exchange. Stage 1: Frog eggs are laid and fertilized. 56 Lesson M Amphibians and Reptiles Stage 4: The adult frog can live and move about on land. Stage 3: Tadpoles begin to grow into adults. They develop legs and lungs. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. How do amphibians develop? How do amphibians reproduce? Most amphibians have external fertilization and require water for reproduction. Most female amphibians lay eggs in a pond or lake. However, some amphibians reproduce away from large bodies of water. For example, some tree frogs that live in the rain forest lay eggs in rainwater that collects in leaves. Reptiles Snakes, lizards, turtles, and crocodiles are reptiles. Reptiles are vertebrates and ectotherms. Most reptiles live their entire lives on land and do not depend on water for reproduction. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. What are some types of reptiles? Turtles have bodies covered with a hard shell. Most turtles can bring their heads and legs into the shell for protection. Alligators and crocodiles are large reptiles that live in or near water. Alligators and crocodiles are predators that live in warmer climates. Lizards and snakes make up the largest group of reptiles. These reptiles have a highly developed sense of smell. An organ in the roof of the mouth senses molecules collected by the tongue. The constant in-and-out motion of the tongue allows a snake or lizard to smell its surroundings. Lizards have movable eyelids and external ears. Most lizards have legs with clawed toes on each foot. Snakes move without legs. They don’t have eyelids or ears. Snakes feel vibrations in the ground instead of hearing sounds. 3. Identify the largest group of reptiles. What are some reptile adaptations? A thick, dry waterproof skin is an adaptation that allows reptiles to live on land. Reptile skin is covered with scales to reduce water loss and help prevent injury. Reptiles breathe with lungs. Reptiles that live in water, like sea turtles, must come to the surface to breathe. Two adaptations allow reptiles to reproduce on land— internal fertilization and laying shell-covered eggs. Sperm are deposited directly into the female’s body. Female reptiles lay fertilized eggs that are covered by tough shells. These eggs are called amniotic (am nee AH tihk) eggs. An amniotic egg supplies the embryo with everything it needs to develop. A leathery shell protects the embryo and yolk. The yolk gives the embryo a food supply. When it hatches, a reptile is fully developed. 4. Determine What is the purpose of the yolk in the amniotic egg? South Carolina Science Essentials 57 After You Read Mini Glossary amniotic egg: the environment for the development of a reptile embryo estivation (es tuh VAY shun): a time of inactivity during hot temperatures hibernation: a time of inactivity during cold weather 1. Review the terms and their definitions in the Mini Glossary. Choose one term that describes an adaptation of an amphibian to its environment. Explain this adaptation in one or two sentences. 2. Complete the concept web below to show the adaptations of reptiles for life on land. 1. 3. Adaptations of Reptiles 5. End of Lesson 58 Lesson M Amphibians and Reptiles 4. Visit msscience.com to access your textbook, interactive games, and projects to help you learn more about amphibians and reptiles. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. 2. Llesson 3 N Birds Standard 6-3.1: Compare the characteristic structures of invertebrate animals (including sponges, segmented worms, echinoderms, mollusks, and arthropods) and vertebrate animals (fish, amphibians, reptiles, birds, and mammals). Standard 6-3.2: Summarize the basic functions of the structures of animals that allow them to defend themselves, to move, and to obtain resources. Before You Read What You’ll Learn the characteristics of birds ■ the adaptations birds have for flight ■ the function of feathers ■ Think of the wide variety of birds. On the lines below, list three things all birds have in common. Read to Learn Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Characteristics of Birds Birds are vertebrates that have two wings, two legs, and a bill or beak. Birds are covered mostly with feathers. They lay eggs with hard shells and sit on their eggs to keep them warm until they hatch. All birds are endotherms. There are more than 8,600 species of birds. Different species have different adaptations. For example, ostriches have strong legs for running. Penguins can’t fly, but they are excellent swimmers. Wrens have feet that allow them to perch on branches. Study Coach Summarize the Main Ideas Read the lesson. Recall and write down the main ideas. Go back and check the main ideas to make sure they are accurate. Adaptations for Flight The bodies of most birds are designed for flight. They are streamlined and have light, strong skeletons. The inside of a bird’s bones is almost hollow. Special structures make the bones strong, but lightweight. A bird’s tail is designed to provide the stiffness, strength, and stability needed for flight. Birds use their tail to steer. Birds need a lot of energy and oxygen to fly. They eat high-energy foods like nectar, insects, and meat. They have a large, efficient heart. A bird’s lungs connect to air sacs that provide a constant supply of oxygen to the blood and make the bird more lightweight. 1. Infer What features do airplanes have that are similar to birds? South Carolina Science Essentials 59 How do birds fly? Birds beat their wings up and down as well as forward and backward. As wind passes above and below the wing, it creates lift. Lift is what allows birds to stay in flight. Functions of Feathers notebook paper, as shown below, to define the key words in this lesson—contour feathers and down feathers. Birds are the only animals with feathers. They have two main types of feathers—contour feathers and down feathers. Contour feathers are strong and lightweight. They give adult birds their streamlined shape and coloring. Contour feathers have parallel strands, called barbs, that extend from the main shaft. Outer contour feathers on the wings and tail help a bird move, steer, and keep from spinning out of control. Feather color and patterns help attract mates. The color patterns also protect birds from predators by helping the birds blend into their surroundings. Have you ever noticed that the hair on your arm stands up on a cold day? This response is one way your body works to trap and keep warm air close to your skin. Birds have down feathers, such as the one below, that trap and keep warm air next to their bodies. In adult birds, down feathers provide a layer of insulation under the contour feathers. Down feathers cover the bodies of some young birds. How do birds care for their feathers? 2. Identify What term is used to describe birds cleaning and rearranging their feathers? 60 Lesson N Birds Feathers need to be cared for to keep birds dry, warm, and able to fly. Birds preen, or use their bills, to clean and rearrange their feathers. During preening, birds also spread oil over their bodies and feathers. This oil comes from a gland found on the bird’s back near its tail. The oil keeps the bird’s skin soft and keeps feathers and scales from becoming brittle. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Define Use a quarter-sheet of After You Read Mini Glossary contour feathers: strong, lightweight feathers that give adult birds their stream-lined shape and coloring down feathers: feathers that trap and keep warm air next to birds’ bodies 1. Review the terms and their definitions in the Mini Glossary. Write two sentences that compare and contrast contour feathers and down feathers. 2. Complete the concept web below. List any six adaptations birds have for flight. 2. 3. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. 1. Adaptations for Flight 6. 4. 5. Visit msscience.com to access your textbook, interactive games, and projects to help you learn more about birds. End of Lesson South Carolina Science Essentials 61 Llesson 3 O Mammals Standard 6-3.1: Compare the characteristic structures of invertebrate animals (including sponges, segmented worms, echinoderms, mollusks, and arthropods) and vertebrate animals (fish, amphibians, reptiles, birds, and mammals). Standard 6-3.2: Summarize the basic functions of the structures of animals that allow them to defend themselves, to move, and to obtain resources. What You’ll Learn the characteristics of mammals ■ how mammals are adapted to different environments ■ the differences among monotremes, marsupials, and placentals ■ Before You Read Make a list of five mammals. Describe one feature that they have in common. Read to Learn Define Words Skim the Define Use two quartersheets of notebook paper, as shown below, to define the key words in this lesson—herbivore, carnivore, omnivore, monotreme, marsupial, and placental. 62 Herbivore Monotreme Carnivore Marsupial Omnivore Placental Lesson O Mammals Mammal Characteristics Moles, dogs, bats, and humans are some examples of mammals. Mammals are vertebrates and endotherms. They live in water and in many different climates on land. They burrow through the ground and fly through the air. Mammals have mammary glands in their skin. A mammal’s skin usually is covered with hair that keeps the body from being too hot or too cold. The hair also protects mammals from wind and water. Some mammals, like bears, have thick fur. Other mammals, like humans, have a few patches of thick hair while the rest of the body has little hair. Dolphins have little hair. Porcupines have quills, which are a kind of modified hair. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. lesson before reading it. Highlight words that you do not know. As you read the lesson, underline the portion of the text that helps you understand the meaning of these words. Why do mammals have mammary glands? In females, the mammary glands produce and release milk for the young. For the first few weeks or months of life, the milk provides all the nutrients the young mammal needs. What kinds of teeth do mammals have? Plant-eating animals are called herbivores. Animals that eat meat are called carnivores. Animals that eat plants and meat are called omnivores. Mammals have teeth that are specialized for the type of food they eat. The four types of teeth are incisors, canines, premolars, and molars. As you can see in the figure below, you usually can tell from the kind of teeth a mammal has whether it eats plants, meat, or both. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Mountain lions are carnivores. They have sharp canines that are used to rip and tear flesh. Humans are omnivores. They have incisors that cut vegetables, premolars that are sharp enough to chew meat, and molars that grind food. Picture This 1. Identify Circle the teeth that carnivores use to rip and tear flesh. Highlight the teeth that omnivores and herbivores use to cut vegetables. Herbivores, like this beaver, have incisors that cut vegetation and large, flat molars that grind it. What body systems do mammals have? Mammals have well-developed lungs. Mammal lungs are made of millions of small sacs called alveoli. Alveoli allow the exchange of carbon dioxide and oxygen during breathing. Mammals also have a complex nervous system that lets them learn and remember more than many other animals. Mammals have larger brains than other animals of similar size. All mammals have internal fertilization. After an egg is fertilized, the developing mammal is called an embryo. Most mammal embryos develop inside the female in an organ called the uterus. 2. Apply What kind of fertilization do all mammals have in common? South Carolina Science Essentials 63 Mammal Types Mammals are divided into three groups based on where their embryos develop. The three groups of mammals are monotremes, marsupials, and placentals. How do monotreme embryos develop? Unlike other mammals, monotremes lay eggs with tough, leathery shells instead of having live births. This small group of mammals includes duck-billed platypuses and spiny anteaters. The female monotreme sits on the eggs for about ten days before they hatch. Monotremes also differ from other mammals because their mammary glands do not have nipples. The milk seeps through the skin onto their fur. The young monotremes lick the milk off the fur. Monotremes live in New Guinea and Australia. Compare the mammary glands of monotremes to other mammals. How do young marsupials develop? Most marsupials carry their young in a pouch. A marsupial embryo develops for only a few weeks within the uterus. When a marsupial is born, it is not fully formed. It has no hair and is blind. The young marsupial uses its sense of smell to find its way to a nipple usually within the mother’s pouch. It attaches to the nipple to feed and finishes developing in the pouch. Most marsupials, such as kangaroos and koalas, live in Australia. The opossum is the only marsupial native to North America. How do placental embryos develop? Most mammals belong to a group called placentals. Placentals are named for the placenta, which is a saclike organ that develops from tissues of the embryo and uterus. An umbilical cord connects the embryo to the placenta. A human embryo is shown in the figure below. Picture This 4. Determine What connects the embryo to the placenta? Human Embryo at Two Months Placenta Umbilical cord 64 Lesson O Mammals Uterine wall Embryo Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. 3. How does the embryo obtain food and oxygen? In the placenta, food, oxygen, and wastes are exchanged between the mother’s blood and the embryo’s blood, but their bloods do not mix. The umbilical cord connects the embryo to the placenta. Food and oxygen are absorbed from the mother’s blood. Blood vessels in the umbilical cord carry food and oxygen to the developing young. The blood vessels also take away wastes. In the placenta, the mother’s blood absorbs wastes from the developing young. The time of development from fertilization to birth is called the gestation period. Gestation periods vary widely, from about 21 days in rats to about 616 days in elephants. Human gestation lasts about 280 days. Mammals Today 5. Define What is the gestation period? There are more than 4,000 species of mammals on Earth today. Mammals can be found on every continent, from cold arctic regions to hot deserts. Each kind of mammal has adaptations that enable it to live successfully within its environment. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. What roles do mammals have? Mammals, like all other groups of animals, have an important role in maintaining a balance in the environment. Large carnivores, such as wolves, prey on herbivores, such as deer. This helps prevent overcrowding and overgrazing. Bats and other small mammals help pollinate flowers. Other mammals spread seeds that stick to their fur. What are some mammals in danger? Some species of mammals are in danger of becoming extinct because their habitats are being destroyed. They are left without enough food, shelter, and space to survive because their habitats are damaged by pollution or developed for human needs. The grizzly bear of North America and Europe is a threatened species. A threatened species is one that is likely to become endangered in the near future. Grizzly bears were once found all over the western half of the United States. Today, they are found only in Alaska, Montana, Wyoming, Idaho, and Washington. Habitat loss due to human settlement has greatly reduced the grizzly bear population. If the grizzly bear population continues to decline and becomes endangered, the species will be in danger of becoming extinct. 6. Explain Why has the grizzly bear population in the United States been greatly reduced? South Carolina Science Essentials 65 After You Read Mini Glossary carnivore: an animal that eats meat herbivore: a plant-eating animal marsupial: a mammal that carries its young in a pouch where it continues to develop after birth monotreme: a mammal that lays eggs with tough, leathery shells omnivore: an animal that eats plants and meat placental: a mammal whose embryos depend on the mother’s placenta for food and oxygen 1. Review the terms and their definitions in the Mini Glossary. Write one or more sentences to explain how herbivores, carnivores, and omnivores are different. 2. Complete the diagram below to identify the three types of mammals. 3. Complete the table below to list the common characteristics of mammals. Common Characteristics of Mammals 1. 2. 3. 4. 5. 6. End of Lesson 66 Lesson O Mammals Visit msscience.com to access your textbook, interactive games, and projects to help you learn more about mammals. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Mammal Types Llesson 3 P Types of Behavior Standard 6-3.7: Compare learned to inherited behaviors in animals. Before You Read On the lines below, explain how you learned a new skill, such as in-line skating or jumping rope. What You’ll Learn the differences between innate and learned behavior ■ how organisms use reflexes and instincts to survive ■ examples of different learned behaviors ■ Read to Learn Identify Main Ideas Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Behavior Animals are different from one another in their behavior. Behavior is the way an organism interacts with other organisms and its environment. Animals are born with certain behaviors, and they learn other behaviors. Anything in the environment that causes a reaction is called a stimulus. A stimulus can be external, such as a male dog entering the territory of another male dog. A stimulus can be internal, such as hunger or thirst. The way an animal reacts to a stimulus is called a response. Getting a drink of water is a response to the internal stimulus of thirst. Innate Behavior A behavior that an organism is born with is called an innate behavior. These types of behaviors are inherited. They do not have to be learned. Innate behavior patterns occur the first time an animal reacts to an internal or external stimulus. For birds, building a nest is an innate behavior. Although the first nest a bird builds may be messy, it is built correctly. Highlight each question head in this lesson. Then use a different color to highlight the answers to the questions. Describe Make a two-tab Foldable, as shown below. Describe the innate and learned behaviors of an animal that you have observed. Innate Behaviors Learned Behaviors South Carolina Science Essentials 67 Why are innate behaviors important? 1. Explain Why do insects have mostly innate behavior? The behavior of animals with short life spans, such as insects, is mostly innate behavior. An insect cannot learn from its parents. By the time the insect hatches, its parents have died or moved on. Innate behavior allows animals to respond quickly. A quick response often means the difference between life and death. Reflex actions are the simplest innate behaviors. A reflex is an automatic response that does not involve a message from the brain. When something is thrown at you, you blink. Blinking is a reflex action. Your body reacts on its own. You do not think about the behavior. What is instinctive behavior? An instinct is a complex pattern of innate behavior. Instinctive behavior begins when an animal recognizes a stimulus. It continues until the animal has performed all parts of the behavior. Spinning a web is an instinctive spider behavior. A spider knows how to spin a web as soon as it hatches. Instinctive behaviors take much more time to complete than reflexes. A spider may spend days building a web. 2. Identify Which animal likely has more learned behaviors—a spider or a monkey? Why? Animals also have learned behaviors. Learned behavior develops over an animal’s lifetime as a result of experience or practice. Animals with more complex brains have more learned behaviors. Fish, reptiles, amphibians, birds, and mammals all learn. Learned behavior helps animals respond to changing situations. In changing environments, an animal that can learn a new behavior is more likely to survive than an animal that cannot learn a new behavior. Learned behavior is important for animals with long life spans. The longer an animal lives, the more likely it is that its environment will change. Can instincts change? Learned behavior can change instincts. Some young birds instinctively crouch and freeze if they see something moving above them. They will crouch and keep still even if the object is only a moving leaf. Older birds have learned that some things that move above them, such as leaves, are not harmful. Learned behavior includes imprinting, trial and error, conditioning, and insight. 68 Lesson P Types of Behavior Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Learned Behavior How does imprinting occur? Imprinting occurs when an animal forms a social attachment to another organism within a short time after birth or hatching. A gosling follows the first moving object it sees after hatching. The moving object is usually an adult female goose. This behavior is important because adult geese have experience in finding food, protecting themselves, and getting along in the world. Animals that become imprinted toward animals of another species have difficulty recognizing members of their own species. What is trial-and-error learning? Behavior that changes with experience is called trial-anderror learning. You learned many skills through trial and error, such as feeding yourself, tying your shoes, and riding a bicycle. Once you learn a skill, you can do it without having to think about it. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. How does conditioning change behavior? Animals often learn new behaviors by conditioning. In conditioning, behavior is changed so that a response to one stimulus becomes linked with a different stimulus. There are two types of conditioning. One type adds a new stimulus before the usual stimulus. Russian scientist Ivan Pavlov performed an experiment to explain how this conditioning works. He knew that hungry dogs salivate when they see and smell food. Pavlov added another stimulus, as seen in the figure below. He rang a bell before he fed the dogs. The dogs connected the sound of the bell with food. The dogs were conditioned to salivate at the sound of a bell even if they were not fed. Compare Make a three-tab Foldable, as shown below. Use a Venn diagram to compare the two types of conditioning. New Stimulus Before Both New Stimulus After Picture This 3. Explain Working with a partner, take turns describing how Pavlov conditioned dogs to respond to a bell. South Carolina Science Essentials 69 4. Analyze Give an example of this second kind of conditioning from your own experiences. Another Type of Conditioning In the second kind of conditioning, a new stimulus is given after a behavior has happened. Getting an allowance for doing chores is an example of this type of conditioning. You do the chores because you want to get your allowance. You have learned, or been conditioned, to perform activities that you may not have done if you had not been offered a reward. How do past experiences help solve problems? In the problem-solving experiment shown below, bananas were placed out of a chimpanzee’s reach. Instead of giving up, the chimpanzee piled up boxes found in the room, climbed them, and reached the bananas. At some time in the past, the chimpanzee must have solved a similar problem. The chimpanzee used past experiences, or insight, to solve the problem. Insight is a form of reasoning that allows animals to use past experiences to solve new problems. When you were a baby, you learned to solve problems using trial and error. As you grow older, you use insight more often to solve problems. Much of adult human learning is based on insight. 5. Describe Why was the chimpanzee able to solve the problem by piling the boxes to reach the bananas? 70 Lesson P Types of Behavior Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Picture This After You Read Mini Glossary behavior: the way an organism interacts with other organisms and its environment conditioning: a way of changing a learned behavior so that a response to one stimulus becomes associated with a different stimulus imprinting: a learned behavior that happens when an animal forms a social attachment to another organism within a short time after birth or hatching innate behavior: a behavior that an organism is born with insight: a form of reasoning that uses past experiences to solve new problems instinct: a complex pattern of innate behavior, such as spinning a web reflex: an automatic response that does not involve a message from the brain 1. Review the terms and their definitions in the Mini Glossary. Write a sentence that explains the difference between instinct and insight. 2. Fill in the graphic organizer below with the different types of animal behavior. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Types of Animal Behavior Innate behavior 3. How did finding answers to the question heads help you learn about types of behavior? Visit msscience.com to access your textbook, interactive games, and projects to help you learn more about the types of behavior. End of Lesson South Carolina Science Essentials 71 Llesson 3 Q A The Atmosphere Standard 6-4.1: Compare the composition and structure of Earth’s atmospheric layers (including the gases and differences in temperature and pressure within the layers). Standard 6-4.2: Summarize the interrelationships among the dynamic processes of the water cycle (including precipitation, evaporation, transpiration, condensation, surface-water flow, and groundwater flow). What You’ll Learn how the atmosphere supports life on Earth ■ what makes up the atmosphere ■ about the water cycle Before You Read ■ Study Coach Air is everywhere. It’s always there. Without it, Earth would be unfit for life. Have you ever wondered how air keeps us alive? Write your ideas below. Read to Learn the text, create a quiz question for each subject. When you have finished reading, see if you can answer your own questions correctly. Investigating Air Classify Make the following Composition of the Atmosphere Foldable to help you organize information about the things that make up Earth’s atmosphere. 72 Lesson Q The Atmosphere An Italian scientist named Galileo Galilei (1564–1642) thought that air was more than just empty space. He weighed a container, injected air into it, and weighed it again. He observed that the container weighed more after air had been added. Galileo concluded that air has weight, so it must contain matter. Today, scientists know other facts about Earth’s atmosphere as well. Air stores and releases heat, and it holds moisture. Because air has weight, it can exert pressure. All of these properties, when combined with energy from the Sun, create Earth’s daily weather. The atmosphere is the layer of gases surrounding Earth. It provides Earth with the gases that organisms need to live. The atmosphere protects living things from harmful doses of ultraviolet radiation and X-ray radiation. It absorbs heat from the Sun and keeps Earth warm. The atmosphere is a mixture of gases, water, and tiny particles of solids and other liquids. Gravity keeps the atmosphere around Earth and prevents it from moving into space. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Create-a-Quiz As you read What gases are in Earth’s atmosphere? Nitrogen makes up about 78 percent of the atmosphere. Oxygen, the gas necessary for human life, makes up about 21 percent. The rest is made up of trace gases or gases that are found in extremely small amounts. Two of the trace gases have important roles within the atmosphere. Water vapor (H2O) is critical to weather. It is responsible for clouds and precipitation. The other important trace gas, carbon dioxide (CO2), is needed for plants to make food. It also absorbs heat and helps keep Earth warm. Applying Math 1. Use Percentages What percentage of Earth’s atmosphere is made up of nitrogen and oxygen? What percentage is made up of trace gases? Show your work. What are aerosols? Aerosols (AR uh sahlz) in the atmosphere are solids such as dust, salt, and pollen, and tiny liquid droplets such as acids. Dust gets into the atmosphere when wind picks tiny soil particles off the ground or when volcanoes release ash. Salt enters the atmosphere when wind blows across the oceans. Pollen is released by plants. Human activities, such as burning coal, also can release aerosols. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Layers of the Atmosphere The atmosphere is divided into five layers. These layers are based on temperature changes that occur with altitude, or height above Earth’s surface. The lower layers are the troposphere and the stratosphere. The upper layers are the mesosphere, the thermosphere, and the exosphere. What are the lower layers of the atmosphere? The troposphere (TROH puh sfihr) is the layer of atmosphere closest to Earth’s surface. It reaches upward to about 10 km. The troposphere contains about three fourths of the matter in Earth’s atmosphere. This is also where nearly all clouds and weather occur. About 50 percent of the Sun’s energy passes through the troposphere and reaches Earth’s surface. The rest is reflected back to space. Above the troposphere is the stratosphere (STRAH tuh sfihr). The stratosphere is the layer of atmosphere that exists from about 10 km to about 50 km above Earth’s surface. Most of the atmosphere’s ozone is in the stratosphere. The ozone in the stratosphere absorbs much of the Sun’s ultraviolet radiation. Without the ozone in this layer, too much radiation would reach Earth’s surface, causing health problems for plants and animals. Organize Information Make a Foldable to record information about the troposphere, stratosphere, and upper layers. Upper Layers Stratosphere Troposphere South Carolina Science Essentials 73 What are the upper layers of the atmosphere? Above the stratosphere is the mesosphere (ME zuh sfihr). This layer extends from about 50 km to 85 km above Earth’s surface. It contains little ozone, so much less heat is absorbed. The thermosphere (THUR muh sfihr) is above the mesosphere. This layer reaches from about 85 km to 500 km above Earth’s surface. Temperatures in the thermosphere can reach more than 1,700°C. This layer helps filter out harmful rays from the Sun. Parts of the thermosphere and mesosphere contain electrically charged particles called ions. This zone is called the ionosphere (i AH nuh sfihr). The ionosphere can reflect AM radio waves, making long-distance communication possible. The outermost layer of the atmosphere is the exosphere. It contains few atoms. No clear border separates the exosphere from space. 2. Convert Percentages to Fractions Earth’s surface is about 70 percent water. What fraction of Earth’s surface is water? What fraction is not water? Show your work. Earth’s Water Earth often is called the water planet. This is because Earth’s surface is about 70 percent water. Water can exist in three separate states—ice, water, and water vapor. The table shows where Earth’s water can be found. Water is found as solid snow or ice in glaciers. In oceans, lakes, and rivers, water exists as a liquid. In the atmosphere, it is a gas called water vapor. Distribution of Earth’s Water Location Oceans Picture This 3. Interpret Data According to the table, where would you find the least amount of Earth’s water? 74 Lesson Q The Atmosphere Amount of Water (%) 97.2 Ice caps and glaciers 2.05 Groundwater 0.62 Rivers and lakes 0.009 Atmosphere 0.001 Total (rounded) 100.00 Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Applying Math What is the water cycle? Earth’s water is in constant motion. The water cycle is the never-ending cycle of water between Earth’s surface and the atmosphere. The Sun’s energy powers the water cycle. The water in Earth’s oceans, rivers, and streams absorbs the Sun’s energy and stores it as heat. 4. Infer Would you expect more evaporation to occur on a sunny day or a cloudy day? Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Evaporation and Condensation When water has enough heat energy, it changes from liquid water into water vapor. This process is called evaporation. Water vapor then enters the atmosphere. Water also is transferred into the atmosphere from plant leaves. This process is called transpiration. As water vapor moves up through the atmosphere, it becomes cooler. The molecules slow down. Eventually, the water molecules change back into droplets of liquid water. This process is called condensation. Precipitation Water droplets get larger when two or more droplets join together. Eventually, these droplets become large enough to be seen. They form a cloud. If the water droplets continue to get larger, they become too large and heavy to remain in the atmosphere. They fall to Earth as precipitation. After the water is on the ground, some of it evaporates. Most water enters streams or soaks into the soil. In the soil, it is called groundwater. Much of this water makes its way back to lakes or to the oceans, where more evaporation occurs and the water cycle continues. The figure below shows the water cycle. 5. Compare and Contrast How is evaporation different from condensation? Droplets inside clouds fall as precipitation, such as rain or snow. As water vapor rises into the air, it cools and forms liquid water again. Tiny water droplets form clouds. Picture This Energy for the water cycle is provided by the Sun. 6. Interpret Scientific Illustrations How does liquid water become part of the atmosphere? Water evaporates from oceans, lakes, and rivers. Plants release water vapor. Rain runs off the land into streams and rivers. Plants also take up some of the water. South Carolina Science Essentials 75 After You Read Mini Glossary aerosols (AR uh sahlz): solids such as dust, salt, and pollen, and tiny liquid droplets such as acids in the atmosphere atmosphere: layer of gases surrounding Earth that protects living things from harmful doses of ultraviolet radiation and X-ray radiation and absorbs and distributes warmth troposphere (TROH puh sfihr): the layer of the atmosphere that is closest to Earth’s surface; contains nearly all clouds and weather water cycle: the never-ending cycle of water between Earth’s surface and the atmosphere 1. Review the terms and their definitions in the Mini Glossary above. Choose two of the terms that are related and write a sentence using both terms. 2. Complete the chart to organize information from this lesson. Earth’s Atmosphere Layers _______________________ gases troposphere _______________________ _______________________ _______________________ evaporation transpiration condensation precipitation _______________________ exosphere 3. You created quiz questions as you read this lesson. How many of the questions can you answer correctly? How did this strategy help you remember information about the atmosphere? End of Lesson 76 Lesson Q The Atmosphere Visit msscience.com to access your textbook, interactive games, and projects to help you learn more about the atmosphere. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Composition Llesson 3 R Ocean Currents and Climates Before You Read If you filled a bowl with water and gently dropped a scrap of paper onto the water surface, it would float. If you want to make the paper move without touching it or tilting the bowl, how could you do it? What are you creating when you make the paper move without touching it or tilting the bowl? Read to Learn What You’ll Learn how wind and Earth’s rotation affect surface currents ■ how ocean currents affect weather and climate ■ the causes and effects of density currents ■ how upwelling occurs ■ Study Coach Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Main Idea-Detail Notes Surface Currents Ocean water never stands still. Currents move the water from place to place constantly. Ocean currents are like rivers that move within the ocean. They exist at both the ocean’s surface and in deeper water. As you read about different types of currents, write notes in two columns. In the left column, write the type of current. In the right column, write details about that current. What causes surface currents? Surface currents are powered by wind and usually move only the upper few hundred meters of seawater. When the global winds blow on the ocean’s surface, they set ocean water in motion. Because of Earth’s rotation, the ocean currents that result do not move in straight lines. Earth’s rotation causes surface ocean currents in the northern hemisphere to curve to their right. Surface ocean currents in the southern hemisphere curve to their left. You can see this on the map on the next page. The turning of ocean currents is an example of the Coriolis effect. Recall that the Coriolis effect also is observed on winds. Winds curve toward their right in the northern hemisphere and toward their left in the southern hemisphere. Understand Cause and Effect Make the following Foldable to help you understand the cause-and-effect relationship of currents. South Carolina Science Essentials 77 We ste rli es Tr ad Tr ad r en t s ind eW ad Tr s ind eW ad Tr The Gulf Stream Much of what is known about surface currents comes from records kept by early sailors. Sailing ships depended on certain surface currents to carry them west and other currents to carry them east. One of the most important currents for sailing east across the North Atlantic Ocean is the Gulf Stream. Find the Gulf Stream current on the map above. The Gulf Stream flows from Florida northeastward toward North Carolina. There it curves toward the east and becomes slower and broader. The Gulf Stream is 100 km wide. It was discovered in the 1500s by Ponce de Leon. In 1770, Benjamin Franklin published a map of the Gulf Stream drawn by Captain Timothy Folger, a Nantucket whaler. Can currents influence climates? Since the Gulf Stream begins near the equator, it is a warm current. It carries heat from the equator to other parts of the ocean. Surface currents like the Gulf Stream, on the eastern coasts of continents, tend to be warm. They bring heat from the equator to other areas of Earth. Currents on the western coasts are usually cold. This can influence the climate of regions near these currents. 78 Lesson R Ocean Currents and Climates Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. es rli ste We C es rli ste We Per u s s G eW ind eW ind m rea eW ind We ste rli es s W est erl ies t St ulf ur Tr ad Tr ad s eW ind rr Cu Tr ad ia follow a current with your pencil. Which way does your pencil turn, left or right? Why? es rli ste We Explain In the figure, rn es rli ste We es rli ste We 1. en s ind eW ad Tr s ind eW ad Tr s ind eW ad Tr Picture This if o nt Curre an Cal eW ind s Jap We ste rli es We ste rli es Earth’s Global Winds Create Surface Currents How do surface currents affect the climates of Iceland and Southern California? Based on its name, you might expect Iceland to have a cold climate. However, the warm water of the Gulf Stream helps keep Iceland’s climate mild. The current’s warm water flows past Iceland and heats the surrounding air. This warm air keeps Iceland’s climate mild and its harbors ice-free all year. Southern California is known for its warmth and sunshine. Look at the figure of surface currents on the previous page. Find the California Current. It carries cold water from polar regions toward the equator. Cold surface currents affect the climate of coastal cities. For example, San Francisco has cool summers and many foggy days because of the California Current. 2. Describe What affects the climate of coastal cities? 3. Sequence of Events Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Density Currents Wind has no effect on water deeper than a few hundred meters. However, currents may develop because of differences in the density of the water. Seawater becomes more dense as it gets colder or when it becomes more salty. Gravity causes dense seawater to sink beneath less dense seawater. As the mass falls, it spreads to less dense waters of the ocean. This creates a density current. A density current is a pattern in the ocean that forms when a mass of dense seawater sinks beneath less dense seawater. Changes in temperature and salinity work together to create density currents. A density current moves very slowly. How does salinity affect density currents? One important density current begins in the cold water north of Iceland. When water freezes, dissolved salts are left behind in the unfrozen water. The very salty water that is left behind is more dense and sinks. Slowly, it spreads along the ocean floor toward the equator and the southern Atlantic Ocean. As the water is sinking near Iceland, the warm surface water of the Gulf Stream moves up from the equator to replace it. Another density current occurs in the Mediterranean Sea. Warm air in the Mediterranean region causes the seawater to evaporate. This leaves salt behind and increases the salinity of the water. The dense, salty water sinks and flows out to the Atlantic Ocean. At the surface, less dense water from the Atlantic Ocean flows into the Mediterranean Sea. Number the events to show the order in which a density current forms near Iceland. saltier water sinks and flows warm water replaces the cold water ocean water freezes South Carolina Science Essentials 79 How do density currents affect climate? 4. Describe What might be affected if density currents stopped? What if the density currents near Iceland stopped forming? Some scientists hypothesize that this has happened in the past and could happen again. Pollution and population growth could lead to large amounts of carbon dioxide in the atmosphere. The carbon dioxide would trap more of the Sun’s heat and raise Earth’s temperature. If Earth’s temperature rose enough, ice couldn’t form easily near the polar regions. Glaciers on land would melt. The freshwater from the glaciers would reduce the salinity of the ocean water. The density currents would weaken or stop. If density currents stopped flowing southward, warm equatorial surface water would no longer flow northward. Earth could face drastic climate changes, including different rainfall patterns and temperatures. Picture This 5. Infer Why does upwelling around Peru make Peru a rich fishing ground? An upwelling is a current in the ocean that brings deep, cold water to the ocean surface. The Coriolis effect pushes surface water away from some coastal regions. Cold water from deep in the ocean rises up to replace it. The illustration shows an upwelling of cold water. The cold water is full of nutrients from dead, decayed organisms. Tiny marine organisms thrive in Surface winds these nutrient-rich areas, which, in turn, attract many fish. As a result, areas of Surface upwelling are imporwater tant fishing grounds Cold water because fish are attracted to the areas to eat the organisms. What happens during El Niño? During an El Niño (el NEEN yoh) event, the winds blowing cold water from the coast of Peru slow down. The Eastern Pacific Ocean becomes warmer, and upwelling is reduced or stopped. Without nutrients provided by upwelling, fish and other organisms cannot find food. This disrupts the rich fishing grounds off Peru’s coast. 80 Lesson R Ocean Currents and Climates Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Upwelling After You Read Mini Glossary density current: current created by the circulation pattern in the ocean that forms when a mass of dense seawater sinks beneath less dense seawater surface current: ocean current that usually moves only the upper few hundred meters of seawater upwelling: ocean current that moves cold, deep water to the ocean surface 1. Review the terms and their definitions in the Mini Glossary above. Choose a term and write a sentence in which you provide an example of that term. 2. Complete the chart below to organize information from this lesson. Ocean Currents Density Currents Surface Currents Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. • travel in the ocean at a depth of • travel in the ocean at a depth of . . • caused by __________ water sinking • set in motion by global ___________ below less ________ water. blowing on Earth’s surface. 3. Earlier, you created two-column notes to help you learn about different types of currents. How did writing notes make learning about currents easier? Visit msscience.com to access your textbook, interactive games, and projects to help you learn more about ocean currents and climate. End of Lesson South Carolina Science Essentials 81 Llesson 3 S Waves What You’ll Learn how wind can form ocean waves ■ how water molecules in a wave move ■ how the Moon and Sun cause Earth’s tides ■ what forces cause shoreline erosion ■ Study Coach Before You Read Have you ever surfed? Maybe you have seen someone surf. How does a surfer who is out in the ocean return to shore? Read to Learn Authentic Questions Understand Cause and Effect Complete the sections for waves and tides on the Foldable you made earlier. 82 Lesson S Waves Waves Caused by Wind Surfers catch and ride waves all the way back to the beach. A wave in water is a rhythmic movement that carries energy through the water. Waves that surfers ride could have started halfway around the world. When wind blows across a body of water, friction pushes the water along with the wind. When wind speed is great enough, water will pile up into waves. Three things affect the height of a wave: the wind speed, the length of time the wind blows, and the distance over which the wind blows. As wind continues to blow, the waves become higher. When the wind stops, waves stop forming. But waves that have already formed will still continue to travel for long distances. What are the parts of a wave? Each wave has a crest, its highest point, and a trough, its lowest part. The wavelength is the horizontal distance between the crests or troughs of two waves. Wave height is the vertical distance from the trough of a wave to the crest. Most waves in the ocean are between 2 m and 5 m high. Some storms have been known to produce waves taller than a six-story building. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Before you begin reading, write down any questions you have about waves. Look for the answers as you read. How do waves move? When you watch a wave, it looks as if the water is moving forward. But unless the wave is breaking onto the shore, the water is not moving forward. Each molecule of water returns to its original position when a wave passes. The molecule may be pushed forward by the next wave, but it will return to its original position when the wave passes. Water molecules move in circular patterns within a wave. 1. What are breakers? A breaker is a collapsing wave. As a wave approaches the shore, it changes shape. The bottom of a wave hits the shallow floor of the ocean and causes friction. This friction slows the bottom of the wave. However, the wave’s crest keeps moving at the same speed. Eventually, the bottom of the wave moves too slowly to support the top of the wave. The crest outruns the trough, and the wave collapses. Water tumbles over on itself, and the wave breaks onto the shore. After a wave crashes, gravity pulls the water back to sea. The figure below shows how waves break. Describe How does a wave affect the position of a water molecule? Wave Motion Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Breaker Wave length decreases Swells Beach Wave height increases Wave direction Sloping bottom Picture This 2. Describe What happens to wave lengths and wave heights as waves move toward the shore? On coasts that slope gently, waves deposit eroded sediments on shore, forming beaches. Beaches extend inland as far as the tides and waves are able to deposit sediments. Waves usually hit the shore at slight angles. This creates a longshore current. Longshore currents move sideways, parallel to the shore. As a result, beach sediments are moved sideways. Longshore currents carry many metric tons of loose sediment from one beach to another. South Carolina Science Essentials 83 Tides During the day, the water level at the ocean’s edge changes. This rise and fall in sea level is called a tide. A tide is a wave that can be thousands of kilometers long but only 1 m to 2 m high in the open ocean. As the crest of this wave approaches the shore, the sea level rises to form high tide. Later in the day, the trough of the wave reaches the shore and the sea level drops to form low tide. The difference between sea level at high tide and low tide is the tidal range. 3. Infer Is a tide always as high as it is long? How are tides created? Tides are created by the gravitational attraction of Earth and the Moon and of Earth and the Sun. Because the Moon is much closer to Earth, it has a stronger pull. The Moon’s gravity pulls at Earth, including its bodies of water. This forms two bulges of water. One is on the side of Earth closest to the Moon, caused by the water’s attraction to the Moon’s gravitational pull. The other is on the side farthest away, created because the Moon is pulling Earth away from the water. These two places will have high tide. As Earth rotates, the bulges follow the Moon. This results in high tide happening around the world at different times. The Sun’s gravity can increase or decrease the Moon’s pull. When the Moon, Earth, and Sun line up, spring tides are created. During spring tides, high tides are higher and low tides are lower than usual. When the Moon, Earth, and the Sun form a right angle, high tides are lower and low tides are higher than usual. These are called neap tides. The different positions of the Moon, Earth, and the Sun during spring tides and neap tides are illustrated below. Picture This 4. Spring Tide Draw Conclusions There are more floods during a spring tide than there are during a neap tide. Why do you think that is? Neap Tide 84 Lesson S Waves Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. What are spring tides and neap tides? After You Read Mini Glossary tide: rhythmic rise and fall in sea level created by the gravitational attraction of Earth and the Moon, and Earth and the Sun wave: in the ocean, the rhythmic movement that carries energy through water 1. Review the terms and their definitions in the Mini Glossary above. Then write a sentence using both vocabulary words. 2. Complete the cause-and-effect chart below to describe how the Moon’s gravitational pull creates high and low tides. CAUSE The Moon is closer to Earth than the Sun. EFFECT The gravitational pull of the _____________________________ Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. is stronger than the pull of the _____________________ on Earth. The Moon’s gravity pulls at Earth. Two __________________________________ form in the ocean. As Earth rotates, the bulges follow the Moon. High ___________________________________ happens around _____________________________________ at different times. 3. You wrote down any questions you had about waves before you read. Were any of your questions answered in the text? If not, ask the class your questions. Visit msscience.com to access your textbook, interactive games, and projects to help you learn more about waves and tides. End of Lesson South Carolina Science Essentials 85 Llesson 3 T What is weather? Standard 6-4.5: Use appropriate instruments and tools to collect weather data (including wind speed and direction, air temperature, humidity, and air pressure). how pressure, wind, temperature, and moisture content of air affect weather ■ how clouds form and how they are classified ■ how rain, hail, sleet and snow develop ■ Study Coach Think-Pair-Share Work with a partner. As you read this lesson, discuss what you already know about the topic and what you learn. Before You Read Have you ever flown a kite or watched someone else fly one? On the lines below, describe how the kite moves in the air. Read to Learn Weather Factors Everybody talks about the weather. It may seem like small talk, but weather is very important to some people. Pilots, truck drivers, farmers, and other professionals study the weather because it can affect their jobs. What is weather? You can look out the window and see that it’s raining, or snowing, or windy. But do you really know what weather is? Weather is the state of the atmosphere at a specific time and place. Weather describes conditions such as air pressure, wind, temperature, and moisture content in the air. How does the Sun affect weather on Earth? Organize Use four quarter sheet note cards to record information about the factors that determine weather. 86 air pressure wind temperature moisture in air Lesson T What is weather? The Sun provides almost all of Earth’s energy. Energy from the Sun evaporates water on Earth. Evaporated water enters the atmosphere and forms clouds. Later, the water falls back to Earth as rain or snow. The Sun also heats Earth. Heat from the Sun is absorbed by Earth’s surface, which then heats the air above it. Because of differences in Earth’s surface, some places in Earth’s atmosphere are warmer and other places are cooler. Air currents and water currents move the heat to different places around Earth. Weather is the result of heat and Earth’s air and water. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. What You’ll Learn What affects temperature? Air is made up of molecules that are always moving randomly, or without any set pattern, even when there is no wind. Temperature is a measure of the average amount of motion of molecules. When the temperature is high, air molecules move rapidly and it feels warm. When the temperature is low, air molecules move more slowly and it feels cold. 1. Have you ever flown a kite? What do you need in order to get the kite off the ground and into the air? Kites fly because air is moving. Air that moves in one direction is called wind. The Sun heats Earth unevenly, but wind helps spread the heat around. As the Sun warms the air, the air expands and becomes less dense. Warm, expanding air has low atmospheric pressure. Cooler air is denser and sinks, which brings high atmospheric pressure. Wind is the result of air moving from areas of high pressure to areas of low pressure. The temperature of air can affect air pressure. When air is cooler, molecules are closer together, creating high pressure. When air is heated, it expands and becomes less dense. This creates lower pressure. Beaches are often windy as a result of air moving from areas of high pressure to areas of lower pressure, as shown in the figure below. Determine When the temperature is high, how do air molecules move? Picture This 2. Label one side of the figure high pressure and one side low pressure. Molecules in air Molecules in air pressure Pressure Pressure Temperature Wind Temperature Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. What causes wind? pressure South Carolina Science Essentials 87 What tools are used to measure wind? 3. Explain Name one tool for measuring wind direction and tell how it works. Some instruments measure wind direction and others measure wind speed. A wind vane, sometimes seen on houses or barns, has an arrow that points in the direction from which the wind is blowing. A wind sock, another tool that shows wind direction, has an open end to catch the wind. The wind sock fills and points in the direction toward which the wind is blowing. An anemometer (a nuh MAH muh tur) is an instrument that measures wind speed. Anemometers have four open cups that catch the wind and cause the anemometer to spin. The faster the wind blows, the faster the anemometer spins. What is humidity? Picture This 4. Determine Circle the figure that shows droplets of water forming. Water vapor molecules Water droplets At cooler temperatures, the molecules in air move more slowly. This slower movement allows the water vapor molecules to stick together. Droplets of liquid water form, as shown on the right in the figure above. This process of liquid water forming from water vapor is called condensation. If enough water is present in the air for condensation to take place, the air is saturated. 88 Lesson T What is weather? Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Heat evaporates water into the atmosphere. Where does the water go? Water vapor molecules fit into spaces among the molecules that make up air. The amount of water vapor held in the air is called humidity. Air does not always hold the same amount of water vapor. More water vapor can be present when the air is warm than when it its cool. At warm temperatures, the molecules of water vapor in the air move quickly. As a result, the molecules do not come together easily, as shown on the left in the figure below. What is relative humidity? Weather forecasters report the amount of moisture in the air as relative humidity. Relative humidity is a measure of the amount of moisture held in the air compared with the amount of moisture the air can hold at a given temperature. If the weather forecaster says that the relative humidity is 50 percent, this means that the air contains 50 percent of the water needed for the air to be saturated at that temperature. Dew Point Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. When the temperature drops, less water vapor can be present in the air. If temperatures are low enough, water vapor will condense to a liquid or form ice crystals. The temperature at which the air is saturated and condensation forms is the dew point. Dew point changes as the amount of water vapor in the air changes. You’ve probably seen water droplets form on the outside of a can of cold soda. The cold can cooled the air around it to its dew point. The water vapor in the air condensed, forming water droplets on the soda can. Something similar occurs when you see dew. Air near the ground cools to its dew point, and then water vapor condenses and forms dew. If temperatures are near 0° C, frost may form. 5. Identify What is the temperature at which condensation forms called? Forming Clouds Clouds form as warm air is forced upward, expands, and then cools, as shown in the figure below. When the air cools, the water vapor molecules in the air come together around particles of dust or salt in the air. These tiny water droplets are not heavy enough to fall to Earth. So, they stay suspended in the air. Billions of these droplets form a cloud. Picture This 6. Interpret Trace the arrows that show moist warm air rising. Moist warm air Heat Damp earth South Carolina Science Essentials 89 Classifying Clouds Clouds are grouped, or classified, by shape and height. Some clouds are tall and rise high into the sky. Some clouds are low and flat. Dense clouds can bring snow or rain. Thin clouds usually appear on sunny days. Three main factors determine the shape and height of clouds—temperature, pressure, and the amount of water vapor in the air. What are the different types of clouds? 7. Classify What are the three main cloud types? Stratus clouds are layered in smooth, even sheets across the sky and may be seen on fair, rainy, or snowy days. Usually stratus clouds form low in the sky. Fog is a stratus cloud that forms when air is cooled to its dew point near the ground. Cumulus (KYEW myuh lus) clouds are large, white, puffy clouds that are often flat on the bottom and sometimes tower high into the sky. Cumulous clouds can be seen either in fair weather or in thunderstorms. Cirrus (SIHR us) clouds are thin, white, feathery clouds. They form high in the atmosphere and are made of ice crystals. Although cirrus clouds are linked with fair weather, they sometimes appear before a storm. Cloud names are sometimes given prefixes to describe the height of the cloud base. Three common cloud prefixes are cirro-, alto- and strato-. Cirro- describes high clouds. Altois used for clouds that form at middle levels. Strato- is used for clouds that form closer to the ground. Cirrostratus clouds are made of ice crystals and form high in the air. Usually cirrostratus clouds are a sign of fair weather. Sometimes they signal a storm is on the way. Altostratus clouds form at middle levels. If these clouds are not too thick, sunlight can filter through them. What types of clouds produce rain and snow? 8. Determine When a cumulus cloud becomes a thunderstorm, what is it called? 90 Lesson T What is weather? Dark clouds that contain rain or snow are called nimbus clouds. Nimbus is a Latin word meaning “dark rain cloud.” The water content of nimbus clouds is so high that only a little sunlight can pass through them. When a cumulus cloud grows into a thunderstorm, it is called a cumulonimbus (kyew myuh loh NIHM bus) cloud. These high clouds can tower almost 18 km. Nimbostratus clouds are layered clouds that usually bring long, steady rain or snowfall. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. How is height used to name clouds? Precipitation Precipitation is water falling from clouds. Precipitation occurs when cloud droplets combine and grow large enough to fall to Earth. The cloud droplets form around tiny particles like salt and dust in the air. Why are some raindrops bigger than others? Compare and contrast Make a four-tab Foldable as shown. As you read, take notes on how the four forms of precipitation are similar and different. You have probably noticed that some raindrops are bigger than others. One reason for this size difference is the strength of updrafts in a cloud. If strong updrafts of wind keep drops in the air longer, they can combine with other drops. As a result, they grow larger. Another factor which affects raindrop size is the rate of evaporation as the drop falls to Earth. If the air is dry, the raindrop will get smaller as it falls. Sometimes the raindrop will evaporate completely before it even hits the ground. Rain Hail Sleet Snow Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. How does temperature affect precipitation? Air temperature determines what kind of precipitation will fall—rain, snow, sleet, or hail. How air temperature affects precipitation is shown in the figures below. When the air temperature is above freezing, water falls as rain. If the air temperature is so cold that water vapor changes to a solid, it snows. Sleet forms if raindrops fall through a layer of freezing air near Earth’s surface, forming ice pellets. During thunderstorms, hail forms in cumulonimbus clouds. Hailstones form when water freezes around tiny centers of ice. Hailstones get larger as they’re tossed up and down by rising and falling air. Most hailstones are small, but sometimes they can get larger than softballs. Of all forms of precipitation, hail causes the most damage. Cloud droplets Warm Raindrops Ice crystals Cloud droplets Cold Cloud droplets Warm Snowflakes Ice Warm Cold Rain Snow Cold Sleet Ice crystal Cloud droplet Picture This 9. Identify In the figures, circle the name of each type of precipitation. Partial melting Hail Warm Hail South Carolina Science Essentials 91 After You Read Mini Glossary dew point: temperature at which air is saturated and condensation forms fog: stratus cloud that forms when air near the ground is cooled to its dew point humidity: amount of water vapor held in the air precipitation: water falling from clouds—including rain, snow, sleet, and hail—whose form is determined by air temperature relative humidity: measure of the amount of moisture held in the air compared with the amount it can hold at a given temperature weather: state of the atmosphere at a specific time and place; determined by air pressure, wind, temperature, and how much moisture is in the air 1. Review the terms and their definitions in the Mini Glossary. Then write one sentence describing today’s weather. Use at least two of the terms. 2. Use these words to fill in the blanks and tell about clouds forming and precipitation: snow, hail, warm moist air, stratus, cumulus, rain, cirrus, sleet, water vapor, clouds condenses into tiny droplets. Droplets suspend in the air, forming Three types of clouds are , Four kinds of precipitation come from clouds: and . , and , . , . 3. You were asked to discuss and study this lesson with a partner. Was this a helpful strategy for learning the information? Why or why not? End of Lesson 92 Lesson T What is weather? Visit msscience.com to access your textbook, interactive games, and projects to help you learn more about weather. , Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. rises, expands, and cools. Llesson 3 U Weather Patterns Standard 6-4.6: Predict weather conditions and patterns based on weather data collected from direct observations and measurements, weather maps, satellites, and radar. Standard 6-4.4: Summarize the relationship of the movement of air masses, high and low pressure systems, and frontal boundaries to storms (including thunderstorms, hurricanes, and tornadoes) and other weather conditions. Before You Read Have you ever gone into a basement or an attic? Describe how the temperature felt compared to the rest of the building. What You’ll Learn how weather is related to fronts and high and low pressure areas ■ about different types of severe weather ■ Read to Learn Key Terms Highlight the key Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Weather Changes Sometimes when you leave school in the afternoon, the weather is different from what it was earlier in the morning. Weather constantly changes. terms and their meanings as you read this lesson. What are air masses? An air mass is a large body of air that has the same temperature and moisture content as the area over which it formed. For example, an air mass that develops over land is drier than one that develops over water. An air mass that develops in the tropics is warmer than one that develops over northern regions. When weather changes from one day to the next, it is because of the movement of air masses. How does air pressure affect the weather? Pressure in the atmosphere varies over Earth’s surface. You may have heard a weather forecaster talk about high- and low-pressure systems. Low-pressure systems are masses of rising air. When air rises and cools, clouds form. That’s why areas of low pressure usually have cloudy weather. But high-pressure air masses have a sinking motion. As a result, it’s hard for air to rise and for clouds to form. So, high pressure usually means nice weather. Classify Make a four-tab Foldable as shown. As you read, take notes on the four different fronts. warm fronts cold fronts occluded fronts stationary fronts South Carolina Science Essentials 93 What are cyclones and anticyclones? 1. Describe What type of weather are cyclones associated with? Winds blow from areas of high pressure to areas of low pressure. In the northern hemisphere, when wind blows into a low-pressure area, Earth’s rotation causes the wind to swirl in a counterclockwise direction. These large, swirling areas of low pressure are called cyclones. Cyclones are associated with stormy weather. Winds blow away from an area of high pressure. In the northern hemisphere, Earth’s rotation causes these winds to swirl in a clockwise direction. High-pressure areas are associated with fair weather and are called anticyclones. Fronts A boundary between two air masses that have different temperature, density, or moisture is called a front. There are four main types of fronts, including cold, warm, occluded, and stationary. Picture This 2. Identify Color the arrow showing cold air movement in the cold front blue. Color the arrow showing warm air movement in the warm front red. A cold front occurs when cold air moves toward warm air, as shown on the left in the figure below. The cold air goes under the warm air and lifts it. As the warm air is lifted, it cools and water vapor condenses, forming clouds. If there is a large difference in temperature between the cold air and the warm air, thunderstorms and tornadoes may form. What is a warm front? Warm fronts form when lighter, warmer air moves over heavier, colder air, as shown on the right in the figure below. In a warm front, wet weather may last for days. Warm air Cold Front 94 Cold air Warm air Cold air Lesson U Weather Patterns Warm Front Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. What is a cold front? What is an occluded front? Most fronts involve two air masses. But occluded fronts involve three air masses—cold air, cool air, and warm air. An occluded front, as shown in the figure below, may form when a cold air mass moves toward cool air with warm air in between. The cold air forces the warm air up. The warm air is then closed off from the surface. The term occlusion means “closure.” Picture This 3. Warm air Interpret Color the arrows red that show where the warm air is closed off from the surface in the occluded front. Cool air Cold air Occluded Front Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. What is a stationary front? A stationary front occurs when a boundary between air masses stops moving, as shown in the figure below. Stationary fronts can stay in the same place for several days. Often there is light wind and precipitation at the stationary front. Picture This 4. Identify Circle the area in the stationary front where neither the cold air nor warm air is moving. Warm air Cold air Stationary Front Severe Weather You usually can do your daily activities regardless of the weather. However, some weather conditions, like blizzards, tornadoes, and hurricanes, can force you to change your plans. South Carolina Science Essentials 95 What causes thunderstorms? During thunderstorms, heavy rain falls, lightning flashes, and thunder rumbles. Hail might fall. What causes these weather conditions? Thunderstorms occur in warm, moist air masses and along fronts. Warm, moist air is forced up. It cools and condensation begins, forming cumulonimbus clouds. When rising air cools, water vapor condenses into water droplets or ice crystals. Smaller droplets collide and form larger ones. The larger, heavier droplets fall through the cloud toward Earth’s surface. The falling droplets collide with more droplets and get bigger. Raindrops cool the air around them. The cool, dense air sinks. Sinking, rain-cooled air and strong updrafts of warmer air cause the strong winds that often come during thunderstorms. Hail may form as ice crystals fall. Explain How do water droplets falling out of a thundercloud get bigger as they fall toward Earth’s surface? What damage do thunderstorms cause? Sometimes thunderstorms stall in one area, causing heavy rains. When streams can no longer hold all the water running into them, flash floods occur. Because they occur with little warning, flash floods are dangerous. Thunderstorms often bring strong winds that can cause damage. If a thunderstorm has winds over 89 km/h, it is called a severe thunderstorm. Hail from thunderstorms can dent cars, break windows, and flatten crops. What causes lightning? Inside a storm cloud, warm air is lifted rapidly as cooler air sinks. This movement of air can cause different parts of a cloud to have opposite charges. When an electrical current runs between areas with opposite charges, lightning flashes. Lightning can occur between two clouds, inside one cloud, or between a cloud and the ground. 6. Determine What causes different parts of a cloud to have opposite charges? 96 Lesson U Weather Patterns What causes thunder? Thunder comes from the rapid heating of air around a bolt of lightning. Lightning can reach temperatures of about 30,000° C. That’s five times hotter than the surface of the Sun. This heat causes air around the lightning to expand rapidly. Then the air cools quickly and shrinks. Because of the sudden expanding and shrinking, molecules in the air move more rapidly. The rapid movement of molecules creates sound waves. Thunder is the sound waves you hear. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. 5. What are tornadoes? Some severe thunderstorms produce tornadoes. A tornado is a violently rotating column of air that touches the ground. Severe thunderstorms produce wind at different heights which blow at different speeds and in different directions. This difference in wind speed and direction is called wind shear. Wind shear creates a rotating column parallel to the ground. Updrafts in a thunderstorm can tilt the rotating column upward, creating a funnel cloud. If the funnel cloud touches the ground, it is called a tornado. The figure below shows a diagram of a tornado. Notice the different levels of winds and the rotating updraft. The strong updraft usually forms at the base of a type of cumulonimbus cloud called a wall cloud. 7. Identify What is a violently rotating column of air that touches the ground called? Upper-level winds Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Rotating updraft Mid-level winds Wall cloud Picture This Dust envelope Main inflow 8. Identify Find the updraft and trace over it with your pencil. How much damage can a tornado do? Winds from tornadoes can rip apart buildings and tear trees from the ground. If the winds of a tornado blow through a house, they can lift off the roof and blow out the walls. It can look as though the building exploded. In the center of a tornado is a powerful updraft. The updraft can lift animals, cars, and even houses into the air. Tornados do not last long, but they are very destructive. In May of 1999, thunderstorms produced more than 70 tornadoes in Kansas, Oklahoma, and Texas. These tornadoes caused 40 deaths, 100 injuries, and more than $1.2 billion in damage. South Carolina Science Essentials 97 How are tornadoes ranked? As you have read, winds from tornadoes can cause severe damage. Theodore Fujita, a tornado expert, created a scale to describe and rank tornadoes. The scale, named the Fujita Scale after him, is shown below. The Fujita Scale ranks tornadoes based on how much damage they cause. Tornadoes range from F0 which cause only light damage to F5 which cause incredible damage. Luckily, only about one percent of all tornadoes are in the category of F4 and F5. Picture This 9. Determine Circle the category that describes severe damage. The Fujita Scale Rank F0 F1 F2 F3 F4 Wind speed (km/h) <116 116–180 181–253 254–332 333–419 F5 420–512 Damage Light: broken branches and chimneys Moderate: roofs damaged, mobile homes upturned Considerable: roofs torn off homes, large trees uprooted Severe: trains overturned, roofs and walls torn off Devastating: houses completely destroyed, cars picked up and carried elsewhere Incredible: total demolition 10. Identify What are two storms similar to hurricanes? The most powerful storm is a hurricane. A hurricane is a large, low-pressure system that forms over the warm Atlantic Ocean and has winds of at least 119 km/h. It is like a machine that turns heat energy from the ocean into wind. Similar storms are called typhoons in the Pacific Ocean and cyclones in the Indian Ocean. Hurricanes are similar to low-pressure systems over land—only stronger. In the Atlantic and Pacific Oceans, low-pressure systems sometimes develop near the equator. In the northern hemisphere, winds around this low pressure rotate counterclockwise. As the storms move across the ocean, they gain strength from the heat and moisture of warm ocean water. What happens when a hurricane reaches land? Hurricanes can strike land with great force. The high winds sometimes produce tornadoes. Heavy rains and high waves cause large amounts of damage. Sometimes floods follow the heavy rains and cause additional damage. Hurricanes can destroy crops, tear down buildings, and kill humans and animals. 98 Lesson U Weather Patterns Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. What is a hurricane? What happens to the hurricane on land? As long as the hurricane remains over water, it gets energy from the warm moist air rising from the ocean. In the figure below, small rising arrows show the movement of warm air from the water below. Cool air goes down through the eye, or center, of the hurricane. The storm needs this energy from the ocean water. When a hurricane reaches land, it loses its energy supply and the storm loses its power. Outflow Descending air Warm moist air Picture This 11. Identify Highlight all the arrows moving counterclockwise. Eye Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Spiral rain bands What is a blizzard? Severe storms also can occur in the winter. If you live in the northern United States, you may have experienced the howling wind and blowing snow of a blizzard. A blizzard is a winter storm with conditions that include very cold temperatures, high winds, and blowing snow that makes it difficult to see. A blizzard usually lasts at least three hours. How can you stay safe during severe storms? When severe weather approaches, the National Weather Service issues a watch or a warning. A watch tells you that even though the weather isn’t dangerous yet, it may become dangerous soon. During a watch, stay tuned to a radio or television station that is reporting the weather. When a warning is given, the weather is already severe. During a severe thunderstorm or tornado warning, go to a basement or to a room in the middle of the house away from windows. When a hurricane or flood watch is given, be prepared to leave home. During a blizzard, stay indoors. 12. Explain What does a weather watch tell you? South Carolina Science Essentials 99 After You Read Mini Glossary air mass: large body of air that has the same characteristics of temperature and moisture content as the area where it formed blizzard: severe winter storm with temperatures below –12° C, winds of at least 50 km/h, and blowing snow that causes poor visibility that lasts at least three hours front: boundary between two air masses with different temperature, density, or moisture hurricane: large, severe storm that forms over tropical oceans and has winds of at least 119 km/h tornado: violently rotating column of air in contact with the ground 1. Review the terms and their definitions in the Mini Glossary. Then write a sentence explaining how hurricanes get and keep their strength. 2. Write the name of the correct weather front above each description. Cold air goes under warm air. Warm air is lifted. 3 air masses: cold, cool, warm Warm air closed off from Earth. Neither warm nor cold air is moving. Lighter, warmer air moves over cold air. 3. Did highlighting key terms and their meanings help you learn the information about weather patterns? Would you use this study strategy again? End of Lesson 100 Lesson U Weather Patterns Visit msscience.com to access your textbook, interactive games, and projects to help you learn more about weather patterns. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. warm front, stationary front, occluded front, cold front Llesson 3 V Weather Forecasts Standard 6-4.6: Predict weather conditions and patterns based on weather data collected from direct observations and measurements, weather maps, satellites, and radar. Before You Read How good are you at predicting the weather? On the lines below, list things you consider when you’re deciding what the day’s weather might be like. Read to Learn What You’ll Learn how data are collected for weather maps and forecasts ■ what symbols are used on a weather map ■ Study Coach Sticky Notes As you read Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Weather Observations By looking at the thermometer or at clouds in the sky, you can tell things about the weather. Certain things about weather you know just from where you live. For example, if you live in Florida, you know that it will probably be warm and sunny. this lesson, mark the pages you find interesting or where you have a question. Share these pages with another student or with the teacher. What does a meteorologist do? A meteorologist (mee tee uh RAH luh jist) studies the weather. A meteorologist gathers information about temperature, air pressure, wind, humidity and precipitation. By using tools like computers, Doppler radar, satellites, and weather balloons, a meteorologist makes weather maps and forecasts the weather. Forecasting Weather Meteorologists gather information and make predictions about weather in the future. Because storms can be dangerous, it is important to know if a storm is coming. The National Weather Service uses two sources to predict the weather. They collect information, or data, from the upper atmosphere. They also collect data from Earth’s surface. Organize Make a Foldable like the one shown below to help you learn about weather forecasts. Meteorologist Weather Symbols Weather Map Weather Instruments South Carolina Science Essentials 101 Station Models Meteorologists gather data from Earth’s surface. Then this data is recorded on a map. A station model shows weather conditions at a specific location using symbols on a map. Information coming from station models and from instruments in Earth’s atmosphere is put into computers and helps forecast weather. Describe What does a station model show? Weather maps have lines that connect locations with the same temperature or the same pressure. An isotherm (I suh thurm) is a line that connects places with the same temperature. Iso means “same.” Therm means “temperature.” You may have seen isotherms on weather maps on TV. Weather maps, like the one below, also have isobars. An isobar is a line that connects two places with the same atmospheric pressure. Isobars show how fast wind is blowing in an area. When isobars are drawn close together, there is a big difference in air pressure. This means a strong wind is blowing. When isobars are drawn farther apart, there is little difference in pressure. Winds in this area are gentler. Isobars also show locations of high- and low-pressure areas. On the weather map below, the pressure areas are drawn as circles with the word High or Low in the middle of the circle. Fronts are drawn as lines and symbols. This information helps meteorologists forecast the weather. Picture This Locate Find the low 1000 1008 1008 sss ss 1000 1008 1016 HIGH 1032 1024 1032 HIGH LOW 75 130 67 4 Portland Legend Cold front Warm front Occluded front Stationary front Isobar Precipitation 41 269 Duluth 35 16 1016 1008 1000 s 58 s Denver 76 183 57 0 1024 HIGH 100 8 LOW s s Springfield ss 6 101 79 125 64 227 76 20 84 134Columbia Little Rock Nashville 5 8 7 0 71 217 54 1 HIGH sssssssss sss s San Diego 76 194 70 89 1 2 72 HIGH 28 4 Tucson LOW 074 54 26 1016 ss s s sss sss 1024 1024 s s sss pressure area by Portland and trace over the circle. s 2. 4 102 Dallas 68 6 LOW 101 6 1024 102 LOW 1016 Lesson V Weather Forecasts Miami 1024 4 85 24 4 75 HIGH Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. How do maps show temperature and pressure? s sss 1. After You Read Mini Glossary isobar: line drawn on a weather map that connects two places with the same atmospheric pressure isotherm: line drawn on a weather map that connects locations with the same temperature meteorologist: person who studies the weather and uses information from Doppler radar, weather satellites, computers, and other instruments to make weather maps and provide forecasts station model: indicates weather conditions at a specific location by using symbols on a map 1. Review the terms and their definitions in the Mini Glossary. Then write a sentence explaining the difference between an isobar and an isotherm. 2. Arrange the following events in order to show how a meteorologist studies weather and uses information. A meteorologist: forecasts weather gathers data on weather conditions makes weather maps Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. First Second Third Visit msscience.com to access your textbook, interactive games, and projects to help you learn more about weather forecasts. End of Lesson South Carolina Science Essentials 103 Llesson 3 W Earth’s Weather Standard 6-4.7: Explain how solar energy affects Earth’s atmosphere and surface (land and water). Standard 6-4.8: Explain how convection affects weather patterns and climate. how clouds form what causes precipitation ■ what causes wind ■ ■ Study Coach Mapping Definitions As you read, make a definition map to describe and define vocabulary words. Your map should include questions about each word, such as, “What is it?” and “What are some examples?” Organize Information Make the following Foldable to help you organize information about Earth’s weather. 104 Lesson W Earth’s Weather Before You Read Hot, cold, windy, snowy, sunny, cloudy—these are all ways to describe weather. What is your favorite kind of weather? Describe it. Read to Learn Weather A weather bulletin has been issued for your area. Heavy snow is expected during the night. Will the schools be closed? Will people be able to get to work? How might this weather affect your family? Weather describes the current condition of the atmosphere, including temperature, cloud cover, wind speed, wind direction, humidity, and air pressure. A meteorologist (mee tee uh RAH luh jist) uses this information to forecast, or predict, the weather. What is temperature? Recall that the Sun’s energy powers the water cycle. In fact, the Sun is the source of almost all of the energy on Earth. When the Sun’s rays reach Earth, energy is absorbed. As gas molecules absorb more energy, they move faster and farther apart. Temperature is a measure of how fast air molecules are moving. The faster the molecules move, the higher the temperature. Temperature is measured with a thermometer. A thermometer has a scale divided into degrees. The two scales commonly used to measure temperature are the Celsius and Fahrenheit scales. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. What You’ll Learn How does energy move through the atmosphere? Fast-moving molecules transfer energy to slower-moving molecules when they bump into each other. This transfer of energy is called conduction. Conduction transfers heat from Earth’s surface to nearby molecules in the air. The heated air rises. As it rises, it starts to cool. When the rising air becomes cooler than the air around it, it sinks again. The process of warm air rising and cool air sinking is called convection. Convection is the main way heat is moved throughout the atmosphere. How conduction and convection transfer heat on Earth is shown in the illustration below. Picture This Cool air pushes warm air upward, creating a convection current. 1. Interpret Scientific Illustrations Highlight Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. the processes of conduction and convection on the diagram. A few centimeters of air near the surface are heated by conduction. Energy from the Sun warms the surface. How is temperature related to air pressure? The weight of air exerts pressure. Air pressure decreases as altitude increases. As you go higher, the weight of the atmosphere above you is less. Temperature and air pressure are related. When air is heated, its molecules move faster, and the air expands. This makes the air less dense so it exerts less pressure on anything below it. The lighter, warmer air moves upward. Cooled air becomes more dense and sinks as the molecules slow down and move closer together. Sinking air produces more pressure. So, rising air usually means lower pressure and sinking air means higher pressure. Air pressure varies over Earth’s surface. 2. Infer Is air pressure likely to be greater at the top or the base of a mountain? Why? South Carolina Science Essentials 105 What is humidity? As air warms up, it can cause water that is touching it to evaporate and form water vapor. Humidity is the amount of water vapor in the atmosphere. Warm air causes evaporation to occur more quickly. Warm air also can hold more moisture. When air is holding as much water vapor as it can, it is said to be saturated and condensation may occur. The dew point is the temperature at which air becomes saturated and condensation can occur. Describe When is air saturated? What is relative humidity? Suppose a mass of air is chilled. The amount of water vapor in the air does not change unless condensation occurs. However, less moisture can be evaporated into the chilled air. Relative humidity is a measure of the amount of water vapor in the air compared to the amount that could be held at that temperature. As air cools, relative humidity increases if the amount of water vapor in the air doesn’t change. When the air holds all the water vapor it can hold at that temperature, the relative humidity is 100 percent. Local TV weather reports sometimes give the dew point on summer days. If the dew point is close to the air temperature, relative humidity is high. If the dew point is much lower than the air temperature, relative humidity is low. Clouds 4. Describe What are clouds made of? One of the best signs that Earth’s atmosphere is in motion is the presence of clouds. A cloud forms when air rises, cools to its dew point, and becomes saturated. Water vapor then condenses onto small particles in the air. If the temperature is warm, the clouds are made up of small drops of water. If the temperature is cold, the clouds are made up of small ice crystals. Clouds are classified according to the height above Earth’s surface at which they form. The most common classification method separates clouds into low, middle, or high groups. What are low clouds? Clouds in the low-cloud group form at altitudes of 2,000 m or less. These include puffy cumulus (KYEW myuh lus) clouds that form when air currents rise, carrying moisture with them. Sometimes cumulus clouds are signs of fair weather. Other cumulus clouds can produce thunder, lightning, and heavy rain. 106 Lesson W Earth’s Weather Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. 3. Stratus and Nimbostratus Clouds Another type of low cloud is layered stratus (STRA tus) clouds. Stratus clouds form as dull, gray sheets that can cover the entire sky. Nimbostratus (nihm boh STRA tus) clouds form low, dark, thick layers that block the Sun. Stratus and nimbostratus clouds produce precipitation. What are middle clouds? Clouds that form between about 2,000 m and 8,000 m are known as the middle-cloud group. Most of these clouds are of the layered variety. Their names often have the prefix alto- in front of them, such as altocumulus and altostratus. These clouds can hold enough moisture to produce light rain or snow. Sometimes they are made up of a mixture of liquid water and ice crystals. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. How do high clouds form? Some clouds form so high in the atmosphere that they are made up entirely of ice crystals. These are known as the high-cloud group. They include the high, wispy cirrus (SIHR us) clouds. They also include cirrostratus clouds, which are high, layered clouds that can cover the entire sky. Some clouds extend from low levels to high levels of the atmosphere. These are clouds of vertical development. The most common type is cumulonimbus (kyew myuh loh NIHM bus) clouds. The term nimbus usually means the cloud creates precipitation. Cumulonimbus clouds produce the heaviest rains of all. Known as thunderstorm clouds, they start to form at heights of less than 1,000 m but can build to more than 16,000 m high. 5. Precipitation Rain, freezing rain, sleet, snow, and hail are all forms of precipitation. Precipitation forms when drops of water or crystals of ice become too large to be suspended in a cloud and fall to Earth. The type of precipitation that falls depends on temperature. For example, rain falls when the air temperature is above freezing. However, if the air at high altitudes is above freezing while the air near Earth’s surface is below freezing, the result might be freezing rain. Draw Conclusions Which of these clouds means that a thunderstorm is on the way? a. b. c. d. altocumulus altostratus cirrus cumulonimbus South Carolina Science Essentials 107 6. Think Critically Why do hailstones develop in cumulonimbus clouds? Hail is balls of ice that form within a storm cloud. Strong winds inside the cloud toss ice crystals up and down. As the ice crystals move, droplets of water freeze around them. Hailstones keep growing until they are too heavy for the winds to keep up. Then they fall to the ground. Ice crystals Freezing Hail Strong winds 7. Infer If the wind is blowing from west to east, where is the area of high air pressure? Warmer air is less dense and moves upward. This causes regions of low air pressure. When cooled, the molecules in air move closer together. The air becomes more dense and sinks. This forms regions of high air pressure. Air moves from areas of high pressure to low pressure. This movement is called wind. The greater the difference in temperature or pressure between two areas, the stronger the wind. How does air circulate? Picture This 8. Compare and Contrast Do areas near the equator heat up more or less than other regions? What about areas near the poles? 108 Lesson W Earth’s Weather Look at the figure. You can see that the Sun’s rays strike Earth at a higher angle near the equator than near the poles. This is why tropical areas heat up more than polar regions do. Warm air flows toward the poles from the tropics. Cold air flows from the poles toward the equator. But the moving air doesn’t flow in a straight line. Because Earth rotates, winds are pushed to their right in the northern hemisphere and to their left in the southern hemisphere. This is known as the Coriolis (kor ee OH lus) effect. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Wind What are surface winds? Air at the equator is heated by the rays of the Sun. This air expands, becomes less dense, and gets pushed upward. At about 30° latitude, the air is somewhat cooler. This air sinks and then flows toward the equator. As this air flows, it is turned by the Coriolis effect. The result is steady winds that blow from east to west. These steady winds are called the trade winds. Trade winds are also called tropical easterlies. 9. Infer The tropical easterlies are called the trade winds. Why do you think they were given this name? What are westerlies and easterlies? Between 30° and 60° latitude north and south of the equator, winds usually blow from the west. These winds form between the cold air from the poles and warmer air closer to the equator. These winds are called the prevailing westerlies. These regions are known for frequent storms. Similar winds near the poles blow from the east and are known as the polar easterlies. The figure below shows Earth’s major surface winds. Picture This Wind belts Sinking air High Rising air Low Surface winds Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. 10. Polar easterlies High 60º N 30º N Low 0º Equator 30º S High 60º S Prevailing westerlies Interpret Scientific Illustrations The city of Buenos Aires, Argentina is at about 34° latitude south of the equator. What type of winds affect the city’s weather? Trade winds Trade winds Prevailing westerlies Polar easterlies Low High What are jet streams? Jet streams are bands of strong winds that develop at higher altitudes within the zone of the prevailing westerlies. Jet streams are like giant rivers of air. They are important because weather systems move along their paths. South Carolina Science Essentials 109 After You Read Mini Glossary dew point: the temperature at which air is saturated and condensation can occur humidity: the amount of water vapor in the atmosphere precipitation: occurs when drops of water or crystals of ice become too large to be suspended in a cloud and fall to Earth; rain, freezing rain, sleet, snow, or hail relative humidity: a measure of the amount of water vapor in the air compared with the amount that could be held at a specific temperature weather: the current condition of the atmosphere, including cloud cover, temperature, wind speed and direction, humidity, and air pressure 1. Review the terms and their definitions in the Mini Glossary. Choose a term and write a sentence in which you provide an example of that term. 2. Complete the concept map to show factors that affect Earth’s weather. _______________________ Earth’s Weather _______________________ _______________________ wind 3. As you read this lesson, you made definition maps for the vocabulary words you learned. How did the mapping strategy help you? What is another strategy you could use to help you learn new vocabulary? End of Lesson 110 Lesson W Earth’s Weather Visit msscience.com to access your textbook, interactive games, and projects to help you learn more about Earth’s weather. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. air pressure Llesson 3 X Air Movement Standard 6-4.9: Explain the influence of global winds and the jet stream on weather and climatic conditions. Before You Read When you think of the word wind what comes to mind? Brainstorm some words and write them on the lines below. Read to Learn Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Forming Wind Earth is mostly rock or land. Three-fourths of Earth’s surface is covered by the oceans. These two areas strongly affect wind systems all over Earth. Because the Sun heats Earth unevenly, some areas are warmer than others. Remember that warmer air expands and becomes less dense than cold air. As a result, air pressure is lower in areas where air is heated. Wind is the movement of air from an area of higher pressure to an area of lower pressure. What You’ll Learn why different altitudes receive different amounts of solar energy ■ about Coriolis effect ■ how air is affected by land and water surfaces below it ■ Study Coach State the Main Ideas As you read this lesson, stop after each paragraph and put what you have just read into your own words. What is heated air? Different areas of Earth receive different amounts of radiation from the Sun. Why? Because Earth’s surface is curved. The equator receives more radiation than areas north or south of it. The Sun’s rays hit the equator more directly. Because air at the equator is warm, it is less dense. So it is displaced, or moved, by denser, colder air. Remember that when cooler, denser air sinks while warmer, less dense air rises, a convection current forms. The cold, dense air comes from the poles. They receive less radiation from the Sun, because its rays strike the poles at an angle, spreading out the energy. The resulting dense, high-pressure air sinks and moves along Earth’s surface. However, there is more to wind than dense air sinking and less dense air rising. Classify Make a three-column Foldable to help you understand the main causes of air movement. Convection currents Polar jet stream Land breeze Coriolis effect Global winds Sea breeze South Carolina Science Essentials 111 What is the Coriolis effect? 1. Determine What causes moving air and water to appear to turn one way in the southern hemisphere and the opposite way in the northern hemisphere? What would happen if you threw a ball to a person sitting across from you on a moving merry-go-round? By the time the ball got to the opposite side, the other person would have moved and the ball would appear to have curved. Like the merry-go-round, the rotation of Earth causes the Coriolis (kohr ee OH lus) effect. The Coriolis effect causes moving air and water to appear to turn to their left in the southern hemisphere (south of the equator) and to turn to the right in the northern hemisphere (north of the equator) due to Earth’s rotation. This effect is illustrated in the figure below. The flow of air caused by the Coriolis effect and by differences in the amount of solar radiation received on Earth’s surface creates wind patterns on Earth’s surface. These wind patterns influence the weather. N Equ ato r Path of wind without Coriolis effect Picture This 2. Explain Do winds turn to their left or their right north of the equator? S Earth's rotation Global Winds 3. Identify What is the name of the windless, rainy zone near the equator? 112 Lesson X Air Movement How did Christopher Columbus get from Spain to the Americas? The Nina, the Pinta, and the Santa Maria had no source of power other than the wind in their sails. Early sailors used wind patterns to help them navigate the oceans. Near the equator, there sometimes was little or no wind to fill the sails of their ships. It also rained nearly every afternoon. Why? Because air near the equator has been heated by the Sun. Warm air rises, creating low pressure and little wind. The rising air then cools and causes rain. This windless, rainy zone near the equator is called the doldrums. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Actual path of wind Picture This Earth’s Winds 60°N 4. Polar easterlies Identify Which winds are located on either side of the Equatorial doldrums? Westerlies 30°N Trade winds 0° Equatorial doldrums Trade winds 30°S Westerlies 60°S Polar easterlies Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. What winds blow near Earth’s surface? The figure above shows some of the winds that blow near Earth’s surface. These prevailing winds move heat and moisture around Earth. Trade Winds Air descending to Earth’s surface near 30° north latitude and 30° south latitude creates steady winds. These winds blow in tropical regions. Early sailors liked them because they moved their ships along quickly. Sailors named them trade winds because they relied on these winds to help them sail to many places to trade goods. Prevailing westerlies Between 30° latitude and 60° latitude in the northern and southern hemispheres, winds called the prevailing westerlies blow. These winds blow in the opposite direction from the trade winds. Prevailing westerlies cause much of the movement of weather across North America. 5. Explain Why would sailors like trade winds? Polar easterlies Another surface wind, polar easterlies, are found near the poles. Near the north pole, easterlies blow from northeast to southwest. Near the south pole, polar easterlies blow from the southeast to the northwest. South Carolina Science Essentials 113 What winds are in the upper troposphere? 6. Define What are the narrow bands of strong winds that blow near the top of the troposphere? Jet streams are narrow bands of strong winds that blow near the top of the troposphere. The polar jet stream affecting North America forms along a boundary where colder air lies to the north and warmer air lies to the south. It moves faster in the winter because there is a greater difference between cold air and warm air. As the figure below shows, the polar jet stream moves in a wavy west-to-east direction. It is usually found between 10 km and 15 km above Earth’s surface. N Cold air Polar j et stream Picture This Determine Trace with your pencil the direction of the polar jet stream. Is it moving east to west or west to east? Warm air S What are the effects of the jet stream? The jet stream helps move storms across the country from the west to the east. Jet pilots use information about jet streams to help them fly. When flying to the east, planes save time and fuel. Going west, planes avoid the jet stream by flying at a different altitude. Flying from Boston to Seattle may take 30 minutes longer than flying from Seattle to Boston. 8. Infer Why would it take longer to fly from east to west than from west to east? 114 Lesson X Air Movement Local Wind Systems Major weather patterns for the entire planet are determined by global wind systems. Local weather is affected by smaller wind systems. Those who live near large bodies of water experience two such wind systems. They are sea breezes and land breezes. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. 7. Sea Breeze Picture This 9. Interpret What is happening to the warm air in both figures? Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Land Breeze What causes sea breezes and land breezes? Convection currents over areas where the land meets the sea can cause wind. During the day, the Sun’s heat warms the land more than it warms the water. A sea breeze is the movement of air from sea to land during the day. Air over the land is heated by conduction. This heated air is less dense and has lower pressure. Cooler, denser air over the water has higher pressure and flows towards the warmer, less dense air above the land. A convection current results, and wind blows from the sea toward the land. At night, the land and the air above it cools much faster than ocean water. Cooler, denser air above the land moves over the water, as the warm air over the water rises. The movement of air from land to sea is a land breeze. 10. Identify What causes wind over areas where the land and sea meet? South Carolina Science Essentials 115 After You Read Mini Glossary Coriolis (kohr ee OH lus) effect: causes moving air and water to appear to turn left in the southern hemisphere and turn right in the northern hemisphere due to Earth’s rotation jet streams: narrow bands of strong winds that blow near the top of the troposphere land breeze: movement of air from land to sea at night, created when cooler, denser air from the land forces warmer air over the sea sea breeze: movement of air from sea to land during the day when cooler air above the water moves over the land forcing the heated, less dense air above the land to rise wind: the movement of air from an area of higher pressure to an area of lower pressure 1. Review the terms and definitions in the Mini Glossary. Then choose one of the definitions and write it in a sentence in your own words. 2. Fill in the boxes with the correct word, cooler or warmer, to show what occurs in a sea breeze and a land breeze. water _________ air Land Breeze _________ air _________ air land water land _________ air 3. Think of Earth’s shape. How does the shape of Earth affect the amount of heat different areas receive? End of Lesson 116 Lesson X Air Movement Visit msscience.com to access your textbook, interactive games, and projects to help you learn more about air movement. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Sea Breeze Llesson 3 Y What is energy? Standard 6-5.1: Identify the sources and properties of heat, solar, chemical, mechanical, and electrical energy. Standard 6-5.2: Explain how energy can be transformed from one form to another (including the two types of mechanical energy, potential and kinetic, as well as chemical, and electrical energy) in accordance with the law of conservation of energy. Before You Read What does the phrase “She has a lot of energy” mean to you? Read to Learn Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. The Nature of Energy Energy is the ability to cause change. An object that has energy can make things happen. Look around you. Changes are happening. Someone might be walking by. Sunshine might be warming your desk. Maybe you can see the wind move the leaves on a tree. What changes are happening? What You’ll Learn what energy is the difference between kinetic energy and potential energy ■ the different forms of energy ■ ■ Highlight Forms of Energy As you read this lesson, highlight the different forms of energy. Then write an example of each type of energy next to the places you highlighted. When is energy noticed? You have a lot of energy. So does everything around you. But you only notice this energy when a change takes place. When a change happens, energy moves from one object to another. Energy from sunlight moves to the spot on the desktop and makes it warm. Energy from the wind moves to leaves. All objects, including desktops and leaves, have energy. Energy of Motion Things that move can cause change. Suppose a bowling ball rolls down the alley and knocks down some bowling pins. Does this involve energy? A change happens when the pins fall over. The bowling ball causes this change. Since energy is the ability to cause change, the bowling ball has energy. The energy in the movement of the bowling ball makes the pins fall. The energy an object has because of its motion is kinetic energy. So as a bowling ball moves, it has kinetic energy. If an object is not moving, it does not have kinetic energy. Organize Information Make the following Foldable to organize information about the nature of energy, the energy of position, and the different forms of energy. South Carolina Science Essentials 117 How are kinetic energy and speed related? What would happen to the bowling pins if the bowling ball rolls faster? More of the pins might fall down or they might move farther. A faster bowling ball causes more change to happen than a slower bowling ball. The faster the bowling ball goes, the more kinetic energy it has. This is true for all moving objects. Kinetic energy increases as an object moves faster. Apply Does a slowermoving object have more or less kinetic energy than a faster-moving object? Compare and Contrast Make the following Foldable to compare and contrast kinetic energy and potential energy. Picture This 2. Determine Which vase on the shelves has the most potential energy? 118 Lesson Y What is energy? How are kinetic energy and mass related? Suppose you roll a volleyball down the alley at the same speed as a bowling ball. Will the volleyball move the pins as far as the bowling ball will? The answer is no. The volleyball might not knock down any pins. How are the volleyball and the bowling ball different? They are moving at the same speed, but the volleyball has less mass. The volleyball has less kinetic energy than the bowling ball because it has less mass. Kinetic energy increases as the mass of an object increases. Energy of Position An object can have energy even if it is not moving. Look at the vase on top of the bookcase. The vase does not have any kinetic energy because it is not moving. What if it accidentally falls to the floor? Changes happen. Gravity pulls the vase downward. The vase has kinetic energy as it falls. Where did this energy come from? When the vase was sitting on the shelf, it had potential (puh TEN chul) energy. Potential energy is the energy stored in an object because of its position. The position of the vase is its height above the floor. As the vase falls, the potential energy is transformed, or changed, from one form to another. It is transformed into kinetic energy. A vase has more potential energy if it is higher above the floor. Potential energy also depends on mass. The more mass an object has, the more potential energy it has. The objects in the figure have different amounts of potential energy. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. 1. Forms of Energy Food, sunlight, and wind have energy. But they have different kinds of energy. The energy in food and sunlight is different from the kinetic energy in the wind. The warmth you feel from sunlight is different from kinetic energy or potential energy. What is thermal energy? When you sit near a sunny window, you get warm. The feeling of warmth is a sign that you are getting more thermal energy. Thermal energy is energy of an object that increases as the object’s temperature increases. All objects have thermal energy. In the figure below, a cup of hot chocolate has more thermal energy than a bottle of cold water. The bottle of cold water has more thermal energy than a block of ice with the same mass. Picture This 3. Identify Circle the object Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. with the greatest thermal energy. Put a box around the object with the least thermal energy. Your body makes thermal energy all the time. Chemical reactions that happen inside your cells make thermal energy. Where does this energy come from? Thermal energy is released by chemical reactions. Thermal energy comes from another kind of energy called chemical energy. What is chemical energy? Chemical energy is the energy stored in chemical bonds. Some of this energy is released when chemicals are broken apart and new chemicals are made. For example, food has chemical energy that your body uses to help you think, move, and grow. Food has chemicals, such as sugar. The chemicals are made of atoms that are bonded together. Energy is stored in the bonds between atoms. These chemical bonds can be broken down in your body to release energy. Also, the flame of a candle comes from chemical energy stored in wax. When the wax burns, chemical energy changes into thermal energy and light energy. 4. Explain What has stored chemical energy that your body uses? South Carolina Science Essentials 119 What is radiant energy? 5. Summarize When does light energy change to thermal energy? Light from the candle flame travels very fast through the air. It moves at a speed of 300,000 km/s. This is fast enough to circle Earth almost eight times in 1 s. When light hits an object, three things can happen. The light can be absorbed by the object, reflected by the object, or be passed through the object. When an object absorbs light energy, the object can get warmer. The light energy changes into thermal energy. You can feel this happening if you wear a black shirt outside on a sunny day. The energy carried by light is radiant energy. You can use electrical energy to make radiant energy. Imagine a metal heating coil on an electric stovetop. As it is heated, it becomes red hot. The hotter it gets, the more radiant energy it gives off. Electrical energy is being used to make the heating coil warmer. 6. Compare Which of the following can carry the most current? a. b. c. d. 9-V battery 220-V electrical outlet 12-V battery 110-V electrical outlet Electrical energy is used in many ways. Electrical energy is carried by the electric current that comes out of batteries and electrical outlets. Electrical lighting uses electrical energy. Look around at all the devices that use electrical energy. The amount of electrical energy depends on the voltage. The current out of a 120-V electrical outlet can carry more energy than the current out of a 1.5-V battery. Large power plants are needed to make the huge amount of electrical energy people use every day. About 20 percent of the electrical energy made in the United States comes from nuclear power plants. What is nuclear energy? Nuclear power plants use the energy stored in the nucleus of an atom to make electricity. Nuclear energy is the energy in the nucleus of every atom. Nuclear energy can be transformed into other kinds of energy. Releasing nuclear energy is difficult. Complicated power plants are necessary to produce nuclear energy. Releasing nuclear energy from an atom is very different from releasing chemical energy from wood. To do that, all you need is a lighted match. 120 Lesson Y What is energy? Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. What is electrical energy? After You Read Mini Glossary chemical energy: the energy stored in chemical bonds electrical energy: the energy carried by the electric current that comes out of batteries and electrical outlets energy: the ability to cause change kinetic energy: the energy an object has because of its motion nuclear energy: the energy in the nucleus of every atom. potential energy: the energy stored in an object because of its position radiant energy: the energy carried by light thermal energy: the energy of an object that increases as temperature increases 1. Read the key terms and definitions in the Mini Glossary above. On the lines below, explain the difference between the terms potential energy and kinetic energy. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. 2. Match the forms of energy with the correct examples. Write the letter of each example in Column 2 on the line in front of the form of energy it matches in Column 1. Column 1 Column 2 1. potential energy a. the energy that makes a television work 2. kinetic energy b. a lamp giving off light 3. electrical energy c. the energy in food 4. thermal energy d. a ball rolling 5. chemical energy e. a book sitting on a shelf 6. nuclear energy f. the energy in a cup of hot tea 7. radiant energy g. the energy in an atom’s nucleus 3. You were asked to highlight the different forms of energy in this lesson. What do you think would be another way to help you remember the different forms of energy? Visit msscience.com to access your textbook, interactive games, and projects to help you learn more about energy. End of Lesson South Carolina Science Essentials 121 Llesson 3 Z Energy Transformations Standard 6-5.1: Identify the sources and properties of heat, solar, chemical, mechanical, and electrical energy. Standard 6-5.2: Explain how energy can be transformed from one form to another (including the two types of mechanical energy, potential and kinetic, as well as chemical, and electrical energy) in accordance with the law of conservation of energy. What You’ll Learn to apply the law of conservation of energy ■ energy changes form ■ how electric power plants make energy ■ Before You Read Explain how you used one kind of energy today. Read to Learn Highlight the main point in each paragraph as you read this lesson. Study the main points, then state each point in your own words. Energy can have different forms such as chemical, thermal, radiant, and electrical. All around you, at all times, energy is being transformed. This means it is changing from one form to another. You see some of these transformations when you notice a change in your environment. Forest fires are an example of a change involving energy. They can happen naturally because of lightning strikes. Changes also happen as a mountain biker pedals up a hill. How can you track energy transformations? Describe Make the following Foldable. Inside, describe the law of conservation of energy and give examples. Law of Conservation of Energy 122 Lesson Z Energy Transformations A mountain biker’s leg muscles transform chemical energy into kinetic energy as he pedals. The kinetic energy of his leg muscles is transformed into kinetic energy of the bicycle as he pedals. As he moves up the hill, some of this energy is transformed into potential energy. Some energy also is transformed into thermal energy. His body is warmer because chemical energy is being released. The parts of the bicycle are warmer too because of friction. When energy is transformed, heat energy usually is made. People exercising, cars running, and living things growing all produce heat. The Law of Conservation of Energy The law of conservation of energy states that energy is never created or destroyed. The only thing that changes is the form of the energy. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Changing Forms of Energy Identify Main Ideas When the biker is resting at the top of the hill, all of his original energy is still around. Some of his energy changed into potential energy. Some changed into thermal energy. No energy is missing. It can all be accounted for. Changing Kinetic and Potential Energy The law of conservation of energy can be used to identify energy changes in a system. For example, tossing a ball into the air and catching it is a simple system. As the ball leaves your hand, most of its energy is kinetic. As it rises, it gets slower. It loses kinetic energy. The kinetic energy is changed into potential energy. The amount of kinetic energy that it loses equals the amount of potential energy that it gains. The total amount of energy stays the same. 1. Draw Conclusions At what point does the ball have the most potential energy? a. when it reaches its highest point b. when it leaves your hand c. just before you catch the ball d. halfway up in the air Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Energy Changes Form Energy changes form all the time all around you. Many machines transform energy from one kind to another. For example, an automobile engine transforms the chemical energy in gasoline into kinetic energy. Some of the chemical energy also is transformed into thermal energy, making the engine hot. An engine that converts chemical energy into more kinetic energy and less thermal energy is a more efficient engine. New kinds of cars use an electric motor along with a gasoline engine. These engines are more efficient so the car can travel farther on a gallon of gas. How is chemical energy transformed? Chemical energy can be transformed into kinetic energy inside your body. This happens in muscle cells. Chemical reactions take place and cause certain molecules to change shape. Many of these changes make your muscles contract. This makes a part of your body move. Biomass Biomass is the matter in living organisms. Biomass contains chemical energy. When organisms die, chemical compounds in their biomass break down. Bacteria, fungi, and other organisms help change these chemical compounds into simpler chemicals. These simpler chemicals are used by other living things. Thermal energy also is released when these biomass breaks down. For example, as a compost pile decomposes, chemical energy is changed into thermal energy. The temperature of a compost pile can reach 60°C. 2. Summarize What kind of energy does bacteria and fungi help transform? South Carolina Science Essentials 123 How is electrical energy transformed? You use electrical energy every day. When you flip a light switch or turn on a radio, electrical energy is transformed into other forms of energy. You use electrical energy when you plug something into an electrical outlet or use a battery. Hearing Sounds The figure shows how electrical energy is transformed into other kinds of energy when you listen to a radio. A loudspeaker in the radio changes electrical energy into sound waves. The sound waves travel to your ear. This is energy in motion. The energy carried by the sound waves makes parts of your ear move too. This energy of motion is transformed into chemical and electrical energy in nerve cells. The nerve cells send the energy to your brain. Your brain figures out that the energy is a voice or music. Where does the energy go after the brain? It finally is transformed into thermal energy. Picture This Identify What kind of energy travels through the air from a radio? Electrical energy of radio signal Kinetic energy of speaker Sound energy of air Kinetic energy of eardrum and fluid Electrical energy of brain and nerve cells What changes into thermal energy? 4. Check Understanding How can thermal energy be used to make kinetic energy? 124 Lesson Z Energy Transformations Different kinds of energy can be transformed into thermal energy. When something burns, chemical energy changes into thermal energy. Electrical energy changes into thermal energy when a wire that is carrying an electrical current gets hot. Thermal energy can be used to heat buildings and keep you warm. Thermal energy also can be used to heat water. If you heat water to its boiling point, it changes to steam. Steam can be used by steam engines to make kinetic energy. Steam engines were once used on steam locomotives to pull trains. Thermal energy also can be transformed into radiant energy. This happens when you heat a metal bar until it is so hot that it glows and gives off heat. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. 3. Energy Transformations How does thermal energy move? Thermal energy can move from one place to another. A cup of hot chocolate has thermal energy. Its thermal energy moves from the cup to the cooler air around it. Thermal energy only moves from something at a higher temperature to something at a lower temperature. 5. Describe Imagine you are taking a hot pan out of the oven using an oven mitt. Describe where thermal energy moves in this example. 6. Define What machine turns a generator to make electricity? Generating Electrical Energy Where does the electrical energy in an electrical outlet come from? It must be made all the time by power plants. In fossil fuel power plants, coal, oil, or natural gas is burned to boil water. Steam from the boiling water rushes through a turbine. A turbine is a machine that has a set of fan blades that are close together. The steam pushes on the blades and turns the turbine. The turbine rotates a shaft in the generator A generator is a device that changes kinetic energy into electrical energy. All power plants work in a similar way—they use energy to turn a generator. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Are there different kinds of power plants? Almost 90 percent of the electrical energy in the United States comes from nuclear and fossil fuel power plants. Other kinds of power plants are hydroelectric (hi droh ih LEK trihk) and wind. Hydroelectric power plants use generators to change the kinetic energy of moving water into electrical energy. Wind power plants use generators to change the kinetic energy of wind into electrical energy. You can diagram the energy transformations in a power plant using arrows. A power plant that burns coal makes energy through the following energy transformations. Nuclear power plants also use energy transformations like the ones below. chemical thermal kinetic kinetic electrical energy → energy → energy → energy of → energy out of coal of water of steam turbine of generator How are hydroelectric power plants different? Hydroelectric power plants do not change water into steam. This is because the water hits the turbine. So the first two steps in the diagram are not needed. The process starts with the kinetic energy of the water. South Carolina Science Essentials 125 After You Read Mini Glossary generator: a device that transforms kinetic energy into electrical energy law of conservation of energy: states that energy is never created or destroyed turbine: a set of steam-powered fan blades that spins a generator at a power plant 1. Review the terms and their definitions in the Mini Glossary. Write a paragraph about how a turbine and a generator are used to make electrical energy. 2. Fill in the blanks to tell what type of energy is being transformed as a biker rides a bicycle. energy. Energy from the food makes the biker’s muscles contract. So the energy from the food is transformed into energy in the muscles. The movement of the biker’s muscles makes the biker hot. So some of the energy in the muscles is transformed into energy. End of Lesson 126 Lesson Z Energy Transformations The biker’s contracting muscles move the pedals on the bike. So some of the energy in the muscles is transformed into energy in the pedals. Visit msscience.com to access your textbook, interactive games, and projects to help you learn more about energy transformations. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. When a biker eats food, the food is transformed into Llesson AA 3 Sources of Energy Standard 6-5.1: Identify the sources and properties of heat, solar, chemical, mechanical, and electrical energy. Standard 6-5.3: Explain how magnetism and electricity are interrelated by using descriptions, models, and diagrams of electromagnets, generators, and simple electrical motors. Standard 6-5.4: Illustrate energy transformations (including the production of light, sound, heat, and mechanical motion) in electrical circuits. Before You Read What You’ll Learn You must plug in most appliances before they will work. Where does the energy in an electrical outlet come from? Read to Learn Identify Details As you Using Energy Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. what renewable, nonrenewable, and alternative resources are ■ the advantages and disadvantages of using different energy sources ■ Energy is used every day to provide light and heat to homes, schools, and workplaces. The law of conservation of energy states that energy cannot be created or destroyed. It can only change form. If a car or refrigerator cannot create energy, where does the energy come from? read this lesson, highlight the text each time that you read about an energy source. Energy Resources Energy must come from the natural world. The surface of Earth gets energy from two places. It comes from the Sun and radioactive atoms in Earth’s interior. Earth gets far more energy from the Sun than is made in Earth’s interior. Almost all the energy you use today can be traced to the Sun. Even the gasoline used to power a car can be traced to the Sun. Surface of Earth Radiant energy from the Sun Organize Information Make the following Foldable to organize information about the fossil fuels, nuclear energy, hydroelectric energy, and alternative sources of energy. Thermal energy from radioactive atoms South Carolina Science Essentials 127 Fossil Fuels Picture This 1. Identify What three things changed the plant molecules into coal molecules? Fossil fuels are coal, oil, and natural gas. Oil and natural gas were made from the remains of microscopic organisms. These organisms lived in Earth’s oceans millions of years ago. Heat and pressure slowly turned these organisms into oil and natural gas. Coal was formed in a similar way. As shown in the figures below, coal was made from the remains of plants that once lived on land. Through photosynthesis (foh toh SIHN thuh sus), ancient plants transformed the radiant energy from sunlight into chemical energy. The chemical energy is stored in molecules. Over time, heat and pressure changed these molecules into fossil fuel. Chemical energy stored in fossil fuels is released when the fossil fuels are burned. Time Heat Pressure Coal mine Can fossil fuels be replaced? Compare and Contrast Use three quarter-sheets of notebook paper to help you compare and contrast nonrenewable resources, renewable resources, and inexhaustible energy sources. Nonrenewable Resources Renewable Resources Inexhaustible Resources 128 Lesson AA Sources of Energy Most of the energy you use comes from fossil fuels. It takes millions of years to replace each drop of gasoline and each lump of coal that is burned. This means that the amount of fossil fuels on Earth will keep decreasing as it is used. Fossil fuels are nonrenewable resources. A nonrenewable resource is an energy source that is used up much faster than it can be replaced. Disadvantages of Fossil Fuels Burning fossil fuels also makes chemical compounds that cause pollution. Each year billions of kilograms of air pollutants are made by burning fossil fuels. These pollutants cause respiratory illnesses and acid rain. Carbon dioxide gas is made when fossil fuels are burned. This carbon dioxide gas might cause Earth’s climate to warm. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Radiant energy Nuclear Energy Can you imagine 1 kg of fuel that has almost 3 million times more energy than 1 L of gas? What could have so much energy in so little mass? The answer is the nuclei of uranium atoms. When these nuclei break apart, they release huge amounts of energy. This energy is used to make electricity by heating water. The figure shows this process. The water makes steam that spins an electric generator. The generator makes electricity. Picture This 2. Identify What type of energy does the steam and the turbine have in a nuclear power plant? Electrical Energy from Nuclear Energy 1. Nuclear energy of atoms 2. Thermal energy of water Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. 3. Kinetic energy of steam 4. Kinetic energy 5. Electrical energy of turbine Generator What are the advantages of nuclear energy? Making electricity by using nuclear energy helps make the supply of fossil fuels last longer. Nuclear power plants also produce almost no air pollution. In one year, a typical nuclear power plant makes enough energy to supply 600,000 homes with electricity. To do this, it produces only 1 m3 of waste. What are the disadvantages of nuclear energy? One disadvantage of nuclear energy is that uranium is a nonrenewable resource. It comes from Earth’s crust. Another disadvantage is that nuclear waste is radioactive and can be dangerous to living things. Some of the materials in nuclear waste will remain radioactive for many thousands of years. This means nuclear waste must be carefully stored so no radioactivity will be released into the environment for a long time. 3. Determine What are two disadvantages of nuclear energy? South Carolina Science Essentials 129 How can nuclear waste be stored? One way to store nuclear waste is to seal it in a ceramic material that is put in protective containers. Then the containers are buried far underground. The place to bury them has to be chosen carefully. It cannot be near underground water supplies. It also has to be safe from earthquakes and other natural disasters. Earthquakes and other natural disasters could cause the radioactive material to leak. Hydroelectricity Infer Which of the following is a renewable resource? Circle your answer. a. b. c. d. water coal oil natural gas Picture This 5. Identify What type of energy does the water have when it flows through the dam? 1. Potential energy of water The potential energy of water trapped behind a dam can be transformed into electrical energy. Energy made this way is called hydroelectricity. This is shown in the figure below. About 20 percent of the world’s electrical energy comes from water. Hydroelectricity is the largest renewable source of energy. A renewable resource is an energy source that is replaced continually. As long as rivers flow, hydroelectric power plants can make electricity. Hydroelectricity makes little pollution. This is an advantage over some other sources of electricity. However, the production of hydroelectricity does have a major disadvantage. It upsets the life cycle of some animals that live in the water. Dams have caused problems for salmon in the Northwest. Salmon return to the spot where they were hatched to lay their eggs. Many salmon cannot reach these places because of dams. There are plans to remove some dams and build fish ladders to help fish go around other dams. 2. Kinetic energy of water 3. Kinetic energy of turbine 130 Lesson AA Sources of Energy 4. Electrical energy out of generator Long-distance power lines Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. 4. Are energy consumption and production equal? More energy is being consumed, or used, in the United States than is being produced, or made. You use energy every day—to get to school, to watch TV, and to heat or cool your home. The amount of energy used by an average person has increased. Therefore, more energy must be made. The graph shows energy consumption and production by the United States from 1949 to 1999. Applying Math Energy (quadrillion Btu) U.S. Energy Overview, 1949–1999 6. 120 90 Consumed in the United States About what year did the United States start consuming more energy than it produced? Energy imports 60 30 Reading Graphs Produced in the United States 0 1949 1954 1959 1964 1969 1974 1979 1984 1989 1994 1999 Year Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Alternative Sources of Energy There are many ways to make electrical energy. Each has disadvantages that can affect the environment and humans. Alternative resources are being researched. Alternative resources are new sources of energy that are safer and less harmful to the environment. Alterative resources include solar energy, wind energy, and geothermal energy. Solar Energy The Sun is an inexhaustible resource. An inexhaustible resource is an energy source that cannot be used up by humans. The amount of solar energy that hits the United States in one day is more than the total amount of energy used by the country in one year. But less than 0.1 percent of the energy used in the United States comes directly from solar energy. One reason is that solar energy is more expensive to use than fossil fuels. However, as the supply of fossil fuels decreases, it might become more expensive to find and mine fossil fuels. It might also become more expensive to mine them from Earth. Then, it might be cheaper to use solar energy or other energy sources to make electricity. 7. Identify What type of resource is the Sun? South Carolina Science Essentials 131 How is the Sun’s energy collected? Two types of collectors take in the Sun’s rays. Have you ever seen large rectangular panels on the roofs of houses or buildings? These are collectors for solar energy. Thermal Collector If the panels had pipes coming out of them, they were thermal collectors. A thermal collector uses a black surface to absorb the Sun’s radiant energy. Black absorbs more radiant energy than any other color. The thermal collector uses the Sun’s radiant energy to heat water. The water can be heated to about 70°C. The hot water can be pumped through a house to provide heat. It can also be used for washing and bathing. 8. Apply Why are thermal collectors black? Photovoltaic If the panel has no pipes, it is a photovoltaic (foh toh vohl TAY ihk) collector. A photovoltaic is a device that transforms radiant energy directly into electrical energy. Photovoltaics are used in calculators and satellites. They also are used on the International Space Station. Imagine you could go to the center of Earth, about 6,400 km below the surface. As you went deeper and deeper, the temperature would increase. After going only about 3 km, the temperature would be warm enough to boil water. At a depth of 100 km, the temperature could be over 900°C. The heat made inside Earth is called geothermal energy. Some geothermal energy is made when unstable radioactive atoms inside Earth decay. This transforms nuclear energy into thermal energy. At some places deep within Earth, the temperature is hot enough to melt rock. Melted, or molten, rock is called magma. Magma rises up close to the surface through cracks in Earth’s crust. Magma reaches the surface when a volcano erupts. In other places, magma gets close to the surface and heats the rock around it. What are geothermal reservoirs? 9. Determine What does the magma in geothermic reservoirs turn water into? 132 Lesson AA Sources of Energy In some places, magma is very close to Earth’s surface. Rainwater and water from melted snow can seep down to the magma through the cracks and openings in Earth’s surface. The magma heats the water and it can become steam. The hot water and steam can be trapped under high pressure in cracks and pockets. These are called geothermal reservoirs. Geothermal reservoirs are sometimes close enough to the surface to make hot springs and geysers. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Geothermal Energy How is geothermal power made? Wells can be drilled to reach geothermal reservoirs in places where the reservoirs are less than several kilometers deep. Hot water and steam from geothermal energy is used by geothermal power plants to make electricity. Picture This Geothermal Power Plant The steam is cooled in the cooling towers and condenses into water. 10. pumped back down into a geothermic reservoir from a geothermic power plant: steam, hot water, or cool water? The water is pumped back down into the geothermal reservoir. Hot water from a geothermal reservoir forces its way through a pipe to the surface where it turns to steam. Interpret an Illustration Which is es Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. The steam turns a turbine that is connected to an electric generator. The figure shows how geothermal reservoirs make electricity. Geothermal power is an inexhaustible resource. But geothermal power plants can be built only where geothermal reservoirs are close to Earth’s surface, like in the western United States. How are heat pumps used? Geothermal heat usually keeps the temperature of the ground that is several meters deep at 10° to 20°C. This constant temperature can be used to heat or cool buildings by using a heat pump. During the summer, the air is warmer than the ground below. A heat pump sends warm water from the building through the cooler ground. The water cools and then is pumped back to the building to absorb heat. In the winter, the air is cooler than the ground below. Then, the cool water absorbs heat from the ground and releases it from the heat pump into the building. 11. Explain Why does the cool water in the building absorb heat in the summer? South Carolina Science Essentials 133 Energy from the Oceans 12. Explain What kind of resource is the movement of the ocean? The ocean is constantly moving. If you have been to the seashore, you have seen the waves roll in. If you spent the day at the beach, you may have also seen the level of the ocean rise and fall. The rise and fall in the ocean level is called a tide. The movement of the ocean is an inexhaustible source of mechanical energy. Mechanical energy can be transformed into electric energy. Several electric power plants that use the motion in ocean waves, or tidal energy, have been built. How much change in water level is needed? A high tide and a low tide each happen about twice a day. In most places, the level of the ocean changes by only a few meters. In some places, it changes by much more. In the Bay of Fundy in Eastern Canada, the ocean level changes by 16 m between high tide and low tide. Almost 14 trillion kg of water move into or out of the bay between high tide and low tide. This tidal energy makes enough electricity to power about 12,000 homes. Picture This 13. Highlight Use a highlighter to trace the flow of water into and out of the tidal power plant. The figures below show how the power plant that has been built along the Bay of Fundy works. The first figure shows that as the tide rises, water flows through a turbine. The turbine causes a generator to spin, which makes electricity. The water is then trapped behind a dam. The second figure shows that when the tide goes out, the trapped water is released. It flows through the turbine making the generator spin. This makes more electricity. Electric power is made each day for about 10 hours. Tidal energy is a clean, inexhaustible resource. But, only a few places have a large enough difference between high and low tide to build an electric power plant. Tidal Power Plant Ocean Ocean Turbine 134 Lesson AA Sources of Energy Turbine Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. How is tidal energy used to make electricity? Wind Wind is another inexhaustible supply of energy. Modern windmills, like the ones in the figure, transform the kinetic energy of the wind into electrical energy. Electrical energy is made when wind spins the propeller. The propeller is connected to a generator, which makes electricity. These windmills produce almost no pollution. But windmills do make a lot of noise. You also need a large area of land to place a lot of windmills. Also, studies have shown that birds sometimes are killed by windmills. Picture This 14. Infer Why do you think Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. the windmills shown in the figure are placed on top of mountains instead of between hills or mountains? Conserving Energy Fossil fuels are a valuable resource. They are burned to provide energy. Oil and coal can be used to make plastics and other materials. To make the supply of fossil fuels last longer, people need to use less energy. Using less energy is called conserving energy. You can save money by conserving energy. You should turn off appliances like televisions when you are not using them to conserve energy. Keep doors and windows closed tightly when it is hot or cold outside. This will keep heat from leaking out of or into your house. If cars were used less or were made more efficient, they would use less gas and oil, and therefore less energy. You also help conserve energy when you recycle aluminum cans and glass. 15. Describe What is another way you can conserve energy? South Carolina Science Essentials 135 After You Read Mini Glossary alternative resources: new renewable or inexhaustible energy sources inexhaustible resource: an energy source that cannot be used up by humans nonrenewable resource: an energy source that is used up much faster than it can be replaced photovoltaic: a device that transforms radiant energy directly into electrical energy renewable resource: an energy source that is replaced continually 1. Review the terms and their definitions in the Mini Glossary. What is the difference between a renewable resource and a nonrenewable resource? 2. Write as many examples of renewable, nonrenewable, and inexhaustible resources in the chart as you can. Nonrenewable Resources Inexhaustible Resources 3. You were asked to highlight the text each time you read about an energy source. How did this help you learn about energy sources? End of Lesson 136 Lesson AA Sources of Energy Visit msscience.com to access your textbook, interactive games, and projects to help you learn more about sources of energy. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Renewable Resources Llesson BB 3 Electric Charge Before You Read You use electricity every day. What would be different in your life if you didn’t have electricity? Read to Learn Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Electricity To understand electricity, first you must think small—very small. Remember that all solids, liquids, and gases are made of tiny particles called atoms. Atoms are made of even smaller particles called protons, neutrons, and electrons. Look at the figure. Protons and neutrons are held together tightly in the nucleus at the center of an atom. Electrons swarm around the nucleus in all directions. Protons and electrons have electric charge. Neutrons have no electric charge. What You’ll Learn how objects become electrically charged ■ about electric charges ■ about conductors and insulators ■ about electric discharge ■ Find the Main Idea As you read, highlight the main idea of each paragraph. Picture This 1. Label Use three different colored highlighters, crayons, or pencils to mark the protons, neutrons, and electrons. Use a different color for each. What are positive and negative charges? There are two kinds of electric charge—positive and negative. A proton has a positive charge. An electron has a negative charge. Atoms have an equal number of protons and electrons. So, atoms are electrically neutral. They have no overall electric charge. South Carolina Science Essentials 137 Explain Does an object that is positively charged have more electrons than protons or fewer electrons than protons? Compare and Contrast Use two quarter sheets of notebook paper to compare and contrast information about gaining and losing electrons. Gain Electrons Lose Electrons How can electrons move in solids? Electrons can move from atom to atom. They also can move from object to object. Rubbing is one way that electrons can move. Have you ever had clinging clothes when you took them out of the dryer? If so, you have seen what happens when electrons move from one object to another. Imagine rubbing a balloon on your hair. The atoms in your hair hold their electrons more loosely than the atoms in the balloon. The electrons from the atoms in your hair move to the atoms on the surface of the balloon. So, your hair loses electrons and becomes positively charged. The balloon gains electrons and becomes negatively charged. Your hair and the balloon become attracted to one another. Your hair stands on end because of the static charge. What is static charge? Static charge is an imbalance of electric charge on an object. Static charge happens in solids because electrons move from one object to the other. Protons cannot easily move from the nucleus of an atom. So, protons usually do not move from one object to another. How do ions move in solutions? Picture This 3. Describe Look at the figure. How would you describe the chloride and sodium ions in the water? Circle your answer. a. b. c. d. 138 tightly held together all the ions are negative spread out evenly all the ions are positive Lesson BB Electric Charge Sometimes, ions move instead of Chloride ions (Cl–) electrons. When ions move, the charge can move. Table salt, or sodium chloride, is made of sodium ions and chloride ions that are held in place and cannot move through the solid. Ions cannot move through solids, but Sodium ions (Na+) they can move through solutions. Look at the figure. When salt is dissolved in water, the sodium and chloride ions break apart. The ions spread out evenly in the water and form a solution. In the solution, the positive and negative ions are free to move. Solutions that have ions make parts of your body able to communicate with each other. Nerve cells use ions to send signals to other cells. These signals move throughout your body so that you can see, touch, taste, smell, move, and even think. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. 2. Ions An atom can gain electrons. When it does, it becomes negatively charged. An atom also can lose electrons and become positively charged. A positively or negatively charged atom is an ion (I ahn). Electric Forces Remember that electrons in an atom swarm around the nucleus. What keeps the electrons close to the nucleus? The positively charged protons in the nucleus exert an attractive electric force on the negatively charged electrons. Electric force is the force between charged objects. All charged objects exert an electric force on each other. The electric force can attract or it can repel, or push away. Look at the figure below. Objects with unlike charges, like positive protons and negative electrons, attract each other. Objects with like charges repel each other. Two positive objects repel each other. Two negative objects repel each other. + + Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Like charges repel. Foldable to show the differences between like charges and unlike charges. Like Charges Unlike Charges Picture This – Unlike charges attract. + Contrast Make the following – 4. Apply Circle the part of the figure that shows the force between two electrons. 5. Explain What happens as a positively charged object comes closer to a negatively charged object? – Like charges repel. The electric force between two charged objects depends on the distance between them. Electric force also depends on the amount of charge on each object. The electric force between two charges gets stronger as the charges get closer together. As positive and negative charges come closer together, the attraction gets stronger. When two like charges come closer together, they repel each other more strongly. If the amount of charge on at least one object increases, then the electric force between the two objects increases. What are electric fields? Charged objects don’t have to touch each other to exert an electric force on each other. Imagine two charged balloons. They push each other apart even though they do not touch. Why does this happen? Every electric charge has a space, or a field, around it. An electric field is the space in which charges exert a force on each other. If an object with a positive charge is placed in the electric field of another positive object, the objects repel each other. If an object with a negative charge is placed in the electric field of an object with a positive charge, the objects attract each other. Also the closer the objects are, the stronger the electric fields. South Carolina Science Essentials 139 Insulators and Conductors Contrast Make the following Foldable to show the differences between insulators and conductors. Conductors Insulators When you rub a balloon on your hair, the electrons from your hair move to the balloon. But, only the part of the balloon that is rubbed on your hair gains the electrons. Electrons cannot move easily through rubber. So, the electrons that move from your hair to the balloon stay in one place on the balloon. The balloon is an insulator. An insulator is a material in which electrons cannot move easily from place to place. Plastic, wood, glass, and rubber are examples of insulators. A conductor is a material in which electrons can move easily from place to place. An electric cable is made from a conductor coated with an insulator, like plastic. The electrons move easily in the conductor (the wire), but do not move easily in the insulator (the plastic). The insulator keeps the electrons in the conductor so that someone touching the cable won’t get a shock. 6. Determine Give an example of each. Conductor: Insulator: The best conductors are metals, like copper, gold, and aluminum. In a metal atom, some electrons are not attracted as strongly to the nucleus as others. When metal atoms form a solid, the atoms cannot move far. But, the electrons inside the atoms that are not strongly attracted to each nucleus can move easily in a solid piece of metal. Insulators are different. In an insulator, the electrons of an atom are strongly attracted to the nucleus. The electrons in an insulator cannot move easily. Induced Charge 7. Explain How do the extra electrons get on your hand? 140 Lesson BB Electric Charge Have you ever walked on carpet and then touched a doorknob? Maybe you felt an electric shock or saw a spark. Look at the figure on the next page to see what happened. As you walk, electrons rub off the carpet onto your shoes. The electrons spread over the surface of your skin. As your hand gets near the doorknob, the electric field around the extra electrons on your hand repels the electrons in the doorknob. The doorknob is metal, so it is a good conductor. The electrons on the doorknob move easily away from your hand. The part of the doorknob closest to your hand becomes positively charged. This separation of positive and negative charges because of an electric field is called an induced charge. The word induce means “to cause”. You induced, or caused, a positive charge on the doorknob. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. What are the best conductors? Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. A As you walk across the floor, you rub electrons from the carpet onto the bottom of your shoes. These electrons then spread out all over your skin, including your hands. B As you bring your hand close to the metal doorknob, electrons on the doorknob move as far away from your hand as possible. The part of the doorknob closest to your hand is left with a positive charge. If the electric field between your hand and the doorknob is strong enough, charge can be pulled quickly from your hand to the doorknob. The quick movement of extra charge from one place to another place is an electric discharge. Lightning is an example of an electric discharge. Imagine a storm cloud. The movement of air causes the bottom of the cloud to become negatively charged. The negative charge induces a positive charge on the ground below the cloud. Cloud-to-ground lightning strikes when electric charge moves between the cloud and the ground. C The attraction between the electrons on your hand and the induced positive charge on the doorknob might be strong enough to pull electrons from your hand to the doorknob. You might see a spark or feel a mild electric shock. Picture This 8. Describe Look at the figure. When do the electrons on the doorknob first begin to move away from your hand? Circle your answer. a. when you walk across the floor b. when your hand gets close to the doorknob c. when you induce a positive charge d. when you touch the doorknob 9. Determine Is Earth an insulator or conductor? Grounding Lightning is an electric discharge that can cause damage and hurt people. A lightning bolt releases a large amount of electric energy. Even electric discharges that release small amounts of electric energy can cause damage to electrical objects, like computers. One way to avoid damage caused by electric discharges is to make the extra charges flow into Earth’s surface. Earth is a good conductor. Since it is so large, it can absorb, or take in, a large amount of extra charge. You may have seen a lightning rod at the top of a building. The rods are metal and are connected to metal cables. These cables conduct the electric charge into Earth if the rod is struck by lightning. So, the extra charge goes to Earth and the building is protected. South Carolina Science Essentials 141 After You Read Mini Glossary conductor: a material in which electrons can move easily from place to place electric discharge: the quick movement of extra charge from one place to another place electric field: the field, or space, in which charges exert a force on each other electric force: the attraction or repulsion between charged objects insulator: a material in which electrons cannot move easily from place to place. ion: a positively or negatively charged atom static charge: an imbalance of electric charge on an object 1. Read the key terms and definitions in the Mini Glossary above. What would cause the electric force between two objects to increase? Explain. 2. The table below lists the charges of two objects. Use the words attract and repel to describe the electric force between the objects. Electric Force Positive and positive Positive and negative Negative and negative 3. You were asked to highlight the main idea of each paragraph. Did this strategy help you learn about electric charge? Why or why not? End of Lesson 142 Lesson BB Electric Charge Visit msscience.com to access your textbook, interactive games, and projects to help you learn more about electric charge. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Charges of Two Objects Llesson CC 3 Electric Current Standard 6-5.4: Illustrate energy transformations (including the production of light, sound, heat, and mechanical motion) in electrical circuits. Before You Read You can turn on the light in a room any time you wish. Where does the electricity come from? What You’ll Learn about electric currents and voltage ■ how batteries make electric currents ■ what electrical resistance is ■ Read to Learn Study Coach Outline As you read the Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Flow of Charge Lights, refrigerators, TV’s and other things need a steady source of electrical energy that can be controlled. Electric currents are used for steady and controlled electricity. An electric current is the flow of electric charge. In solids, the flowing charges are electrons. In liquids, the flowing charges are ions. Remember that ions can be positive or negative. Electric currents are measured in amperes (A). A model of an electric current is flowing water. Water flows downhill because a gravitational force acts on it. Electrons flow because an electric force acts on them. lesson, make an outline using each heading. Under each heading, write the main ideas that you read. What is a simple circuit? The flow of water can create energy. Higher-energy water Look at the figure. Height Water that is pumped high above the ground Pump has potential energy Lower-energy water because gravity acts on it. As water falls, it loses potential energy. When the water falls on a waterwheel and turns it, the waterwheel gains kinetic energy. The water flows through a continuous loop. A closed, conducting loop that electric charges flow continuously through is a circuit. Picture This 1. Highlight Use a highlighter to mark the flow of water through the continuous loop. South Carolina Science Essentials 143 What are electric circuits? Organize Information Make the following Foldable to write down information about electric circuits. Electric Circuit The simplest electric circuit has a source of electric energy and an electric conductor. In the figure below, the source of electric energy is the battery. The electric conductor is the wire. The wires connect the lightbulb to the battery in a closed path. Electric current flows in the circuit as long as the wires, including the filament wire in the lightbulb, stay connected. e– Picture This 2. Identify Circle the source of electric energy in the figure. e– Battery Wire e– e– 3. Identify In a circuit (like the one in the figure above), what increases the electrical potential energy of the electrons? Think of the example of the waterwheel. The pump increases the gravitational potential energy of the water by raising it from a lower level to a higher level. In an electric circuit, the battery increases the electrical potential energy of electrons. This electrical potential energy can be changed into other forms of energy. The measure of how much electrical potential energy each electron can gain is the voltage of a battery. Voltage is measured in volts (V). As voltage increases, more electrical potential energy is available to be changed into other forms of energy. How does a current flow? The electrons in an electric circuit move slowly. When the ends of a wire are connected to a battery, the battery makes an electric field in the wire. The electric field forces electrons to move toward the positive end of the battery. 144 Lesson CC Electric Current Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. What is voltage? Look at the plus sign on the battery in the figure on the previous page. As electrons move, they bump into other electric charges in the wire. Then, they bounce off in different directions. Electrons start to move again toward the positive end of the battery. An electron can have more than ten trillion of these bumps each second. So, it can take several minutes for an electron to travel even one centimeter. How do batteries work? Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Battery Terminals Batteries have a negative terminal, or end, and a positive terminal. You have learned that the battery in a circuit makes an electric field that forces electrons to move toward the positive terminal of the battery. When the positive and negative terminals of a battery are connected in a circuit, the electric potential energy of electrons in the circuit increases. As electrons move toward the positive terminal, the electric potential energy turns into other forms of energy. This also happens with water. The gravitational potential energy of the water turns into kinetic energy as the water turns the waterwheel. Electrical Potential Energy The battery changes chemical energy into electric potential energy. In the figure on the previous page, the battery shown is an alkaline battery. Between the positive terminal and negative terminal is a moist paste. Chemical reactions in the moist paste move electrons from the positive terminal to the negative terminal. So, the negative terminal becomes negatively charged and the positive terminal becomes positively charged. This makes the electric field in the circuit that causes the electrons to move away from the negative terminal to the positive terminal. The chemical energy is now electrical potential energy. 4. Explain How does the negative terminal of a battery become negatively charged? How long can batteries last? Batteries cannot supply energy forever. Do you know what happens if the lights on a car are left on for a long time? The car battery runs down and the car won’t start. Why do batteries run down? Batteries have only a certain amount of chemicals in them that react to make chemical energy. As long as the battery is used, these chemical reactions happen. The chemicals change into other compounds. When the chemicals are used up, the chemical reactions stop. The battery is then “dead.” 5. Explain Why does a battery “die”? South Carolina Science Essentials 145 Resistance Remember that electrons move more easily through conductors than through insulators. But, even in conductors, the flow of electrons can be slowed down. The measure of how difficult it is for electrons to flow through a material is resistance. The unit of resistance is the ohm (Ω). Insulators have a higher resistance than conductors. You learned that, in a circuit, electrons bump into other electric charges. When this happens some of the electrical energy in the electrons turns into thermal energy in the form of heat or light. The amount of electrical energy that turns into heat and light depends on the resistance of the materials in the circuit. Why are copper wires used in buildings? The amount of electrical energy that turns into thermal energy increases when the resistance of the wire increases. Copper is one of the best conductors of electric energy. It also has a low resistance. So, less heat is made when an electric current flows through copper wire. Copper wire is used in houses and other buildings because copper wire usually will not become hot enough to cause fires. 6. Recognize Cause and Effect What increases when a wire is made longer or thinner? A wire can have high or low electric resistance depending on what the wire is made of. The electric resistance of a wire also depends on the wire’s length and thickness. The electric resistance of a wire increases as the wire becomes longer. The electric resistance also increases as the wire becomes narrower. How do lightbulbs work? 7. Explain Why is tungsten used for lightbulb filaments? 146 Lesson CC Electric Current Lightbulbs have a tiny wire inside called a filament. The filament wire is so narrow that it has a high resistance. Remember that a material that has high resistance can turn electric energy into thermal energy in the form of heat or light. When electric current flows in the filament, the wire becomes hot enough to make light. Why doesn’t the filament melt? The filament is made of tungsten metal. Tungsten has a much higher melting point than most other metals. So, the tungsten metal filament will not melt at the high temperature needed to make light. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. How are length and thickness of a wire related to resistance? After You Read Mini Glossary circuit: a closed, conducting loop that electric charges flow continuously through electric current: the flow of electric charge resistance: the measure of how difficult it is for electrons to flow through a material voltage: the measure of how much electrical potential energy each electron can gain. 1. Review the terms and their definitions in the Mini Glossary. Write one or two sentences to compare resistance in a conductor and an insulator. 2. Complete the graphic organizer to compare and contrast copper wire and tungsten wire using the information below. Copper Wire Tungsten Wire 1. Low Resistance 1. ___________________________ Both 2. ___________________________ Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. ___________________________ Good conductor ___________________________ 2. ___________________________ ___________________________ 3. At the beginning of the lesson, you were asked to create an outline of the lesson. How did the outline help you learn about electric current? Visit msscience.com to access your textbook, interactive games, and projects to help you learn more about electric current. End of Lesson South Carolina Science Essentials 147 Llesson 3 DD Electric Circuits Standard 6-5.4: Illustrate energy transformations (including the production of light, sound, heat, and mechanical motion) in electrical circuits. What You’ll Learn how voltage, current, and resistance are related ■ about series and parallel circuits ■ how to avoid dangerous electric shock ■ Before You Read You use circuits every day. Name some circuits you have used. Read to Learn State the Main Ideas As you read this lesson, stop after each paragraph and write down the main idea in your own words. Picture This 1. Infer Circle the bucket and hose that show greater resistance. Controlling the Current Electric current flows through a circuit when you connect a conductor, like a wire, between the positive and negative terminals of a battery. The amount of current depends on the voltage of the battery and the resistance of the conductor. Imagine a bucket of water with a hose attached in the bottom of it. Look at the figure. If you raise the bucket, you increase the potential energy of the water in the bucket. This causes the water to flow out of the hose faster. This happens with electric current, too. If the amount of voltage increases, the amount of current flowing through a circuit will increase. How do voltage and resistance affect current? As the figure shows, the higher the bucket is raised, the more energy the water has. Increasing the voltage in a battery is like increasing the height of the water. The electric current in a circuit increases if the voltage increases. If the resistance in an electric circuit is greater, less current can flow through the circuit. 148 Lesson DD Electric Circuits Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Study Coach What is Ohm’s law? Applying Math In the nineteenth century, a German scientist named Georg Simon Ohm measured how changing the voltage in a circuit affects the current. He found a relationship among voltage, current, and resistance in a circuit, know as Ohm’s law. Ohm’s law states that when voltage in a circuit increases, the current increases. The equation below shows this relationship. 2. Calculate An iron is plugged in a wall socket. The current in the iron is 5 A. The resistance is 20 Ω. What is the voltage provided by the wall socket? Show your work. Voltage (in volts) current (in amperes) resistance (in ohms) V IR If the voltage in a circuit stays the same, but the resistance changes, the current will change, too. If the resistance increases, the current in the circuit will decrease. Circuits control the movement of electric current by providing paths for electrons to follow. In order for a current to flow, the circuit must be an unbroken path. Imagine a string of lights with tiny light bulbs. In some strings of lights, if only one bulb is burned out, the whole string of lights won’t work. This is an example of a series circuit. Some strings of lights will stay lit no matter how many bulbs burn out. This is an example of a parallel circuit. Organize Information Use two half-sheets of notebook paper to write information about series and parallel circuits. Parallel Circuits Series Circuits What is a series circuit? A series circuit is a circuit that has only one path for the electric current to follow. Look at the figure. If the path is broken, current cannot flow. The bulbs in the circuit will not light. The path could be broken if a wire comes off or if a bulb burns out. The filament in the lightbulb is also part of the circuit. So, if the filament breaks, then the flow of current stops. Picture This 3. Ba tte ry Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Series and Parallel Circuits Predict Look at the figure. What would happen if you remove a wire from one of the lightbulbs? South Carolina Science Essentials 149 What happens when resistance increases? In a series circuit, electrical devices are connected along the same path. So, the current is the same through every device. But, if a new device is added to the circuit, the current will decrease throughout the circuit. Why? Each device has its own electrical resistance. In a series circuit, the total resistance increases as each new device is added. Ohm’s law tells us that if resistance increases and the voltage doesn’t change, the current will decrease. 4. Recognize Cause and Effect A series circuit has 2 lightbulbs on it. What happens to the resistance if you add another lightbulb to the circuit? What is branched wiring? What would it be like if all the electrical devices in your house were on a series circuit? You would have to turn on all the appliances in your house just so you could watch TV. 5. Predict Look at the figure. What would happen to the lightbulb on the right if you remove the lightbulb on the left? Parallel Circuit Ba tte ry Picture This In a parallel circuit, the resistance in each branch can be different. The resistance in a parallel circuit depends on the devices in the branch. If the resistance in one branch is low, then more current will flow through it than in other branches. So, the current in each branch of a parallel circuit can be different. 150 Lesson DD Electric Circuits Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Parallel Circuits Your house, school, and other buildings are wired using parallel circuits. A parallel circuit is a circuit that has more than one path for the electric current to follow. The figure shows a parallel circuit. The circuit branches so that the electrons flow through each of the paths. If one of the paths is broken, electrons will still flow through the other paths. So, you can add or remove a device in one branch and the current will still flow. Protecting Electric Circuits In a parallel circuit, electric current that flows out of a battery or electric outlet increases as more devices are added to the circuit. As the current through the circuit increases, the wires heat up. What are fuses and circuit breakers? If wires get too hot, they can cause a fire. To make sure that wires don’t get too hot, the circuits in your house and other buildings have fuses or circuit breakers. Fuses and circuit breakers limit the amount of current in the wiring. If the current becomes greater than 15 A or 20 A, a piece of metal in the fuse melts or a switch in the circuit breaker opens, stopping the current. The device that caused the problem can be removed. Then, the fuse can be replaced or the circuit breaker can be reset. 6. Electric Power Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. When you use a toaster or a hair dryer, electrical energy changes into other kinds of energy. The rate, or speed, at which electrical energy is changed into other kinds of energy is electric power. In any electric device or electric circuit, the electric power that is used can be found by using the equation below. Explain What do fuses and circuit breakers do? Applying Math 7. Power (in watts) current (in amperes) voltage (in volts) P IV Calculate A toaster is plugged into a wall outlet. The current in the toaster is 10 A. The voltage of the wall outlet is 110 V. How much power in watts does the toaster use? Show your work. The electric power is equal to voltage provided to the electrical device multiplied by the current that flows into the device. The SI unit of power is the watt. The table lists the electric power used by some common devices. Power Used by Common Devices Device Power (in watts) Computer 350 Color TV 200 Stereo 250 Refrigerator 450 Microwave 700–1,500 Hair dryer 1,000 Applying Math 8. Interpret Data How many more watts does a hair dryer use than a color TV? South Carolina Science Essentials 151 How do electric companies measure power? Power is the amount of energy that is used per second. When you use a hair dryer, the amount of electrical energy you use depends on the power of the hair dryer. It also depends on how long you use it. Suppose you used the hair dryer for 10 minutes today and 5 minutes yesterday. You used twice as much energy today than you did yesterday. How much does electrical energy cost? Electric companies make electrical energy and sell it in units of kilowatt-hours. One kilowatt-hour (kWh) is equal to using one kilowatt of power continuously for one hour. This is about the amount of energy needed to light ten 100-W lightbulbs for one hour or just one 100-W lightbulb for 10 hours. An electric company charges customers for the number of kilowatt-hours they use every month. An electric meter on the outside of each building measures the number of kilowatt-hours used in that building. Electrical Safety Picture This 9. Infer Why should you not use an electric device near water? Preventing Electric Shock Never use a device with frayed or damaged electric cords. Unplug appliances before you work on them. For example, if a piece of toast gets stuck in a toaster, unplug the toaster before you take the toast out. Never use an electric device near water. Never touch power lines with anything, including a kite string or ladder. Always pay attention to warning signs and labels. How do electric shocks happen? 10. Identify Is skin a conductor or an insulator? 152 Lesson DD Electric Circuits If an electric current enters your body, you feel an electric shock. Your body is like a piece of insulated wire. The fluids inside your body are good conductors of electric current. The electrical resistance of dry skin is much higher than the fluids in your body. Skin insulates the body in the same way that plastic insulates a copper wire. Remember that electrons cannot move easily in an insulator like plastic. Your skin works in the same way. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Electricity can be very dangerous. In 1997, electric shocks killed about 490 people in the United States. Here are some tips that will help prevent electrical accidents. You actually become part of an electric circuit when current enters your body. The shock you feel can be mild or deadly, depending on the amount of current that flows into your body. How much is too much? Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. The amount of current that can light a 60-W lightbulb is about 0.5 A. If this amount of current enters your body, it could be deadly. Even a current as low as 0.001 A can be painful. The table shows what you would feel when a certain amount of electric current flows through your body. Current’s Effects Amount of Current (in amperes) What You Feel 0.0005 A Tingle 0.001 A Pain 0.01 A Can’t let go 0.025 A 0.05 A Difficult to breathe 0.10 A 0.25 A 0.50 A Heart failure 1.00 A Picture This 11. Interpret Data Describe how you would feel if you were shocked by a current of 0.10 A. How do you keep safe from lightning? Electricity in lightning can be very dangerous. Lightning can harm people, plants, and animals. In the United States, more people are killed every year by lightning than by hurricanes or tornadoes. Most of these lightning deaths happened outdoors. If you are outside and can see lightning or hear thunder, you need to go indoors right away. If you cannot go indoors, you need to take the following steps: • Stay away from open fields and high places • Stay away from tall objects like trees, flagpoles, or light towers 12. Explain Why should you stay away from metal fences when you see lightning or hear thunder? • Stay away from objects that conduct current such as water, metal fences, picnic shelters, and bleachers. South Carolina Science Essentials 153 After You Read Mini Glossary electric power: the rate, or speed, at which electrical energy is changed into other kinds of energy Ohm’s law: the relationship among voltage, current, and resistance; when the voltage in a circuit increases, the current increases parallel circuit: a circuit that has more than one path for the electric current to follow series circuit: a circuit that has only one path for the electric current to follow 1. Review the terms and their definitions in the Mini Glossary. Explain why it is better to have a parallel circuit in your home than a series circuit. 2. Explain the main ideas of Ohm’s law in the cause-and-effect map below. Write increases or decreases in the blanks. Ohm’s Law Voltage increases Effect Electric current Cause Resistance increases Effect Electric current 3. You were asked to write the main idea of each paragraph as you read this lesson. How did you decide which is the main idea for each paragraph? End of Lesson 154 Lesson DD Electric Circuits Visit msscience.com to access your textbook, interactive games, and projects to help you learn more about electric circuits. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Cause Llesson EE 3 What is magnetism? Before You Read Do you have magnets on your refrigerator? Why do magnets stick to a refrigerator and other things? What You’ll Learn how magnets behave how the behavior of magnets and magnetic fields are related ■ why some materials are magnetic ■ ■ Read to Learn Study Coach Create an Outline Use the Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Early Uses Thousands of years ago, people found that a mineral called magnetite attracted other pieces of magnetite. It also attracted bits of iron. When they rubbed small pieces of iron with magnetite, the iron began to act like magnetite. If they let the pieces turn freely, one end pointed north. These might have been the first compasses. Compasses helped sailors and explorers know which direction they were going. Before compasses, sailors and explorers had to look at the Sun and stars to know which direction they were going. headings to make an outline of the information in this lesson. Magnets A piece of magnetite is a magnet. Magnets attract objects made of iron or steel, like nails and paper clips. Magnets also attract or repel other magnets. To repel means “to push away.” Every magnet has two ends. The two ends are called poles. One end is called the north pole. The other end is called the south pole. The figure on the next page shows what happens when you put two magnetic poles together. Two north poles will repel each other. Two south poles also repel each other. But a north pole and a south pole are attracted to each other. 1. Determine Do the north poles of two magnets attract or repel each other? South Carolina Science Essentials 155 Picture This 2. Highlight Use one color to circle the poles that are attracted to each other. Then use another color to circle the poles that repel each other. Poles That Repel or Attract Two north poles repel Two south poles repel Opposite poles attract Remember that a force is a push or a pull that can make an object move. Gravitational and electric forces can act on an object even when objects are not touching. Magnetic force also can act on objects when they are not touching. Notice that the magnets in the figure above are not touching and a magnetic force is acting on them. A magnet can even make an object move without touching it. The magnetic force gets weaker when the magnets move farther apart. A magnetic field is the space around a magnet where the magnetic force is. Magnetic fields are around all magnets. If you sprinkle iron fillings near a magnet, the iron filings will show the magnetic field lines of the magnet. The figure below shows these curved lines. The lines start on one pole and end on the other. Picture This 3. Highlight Trace the magnetic field lines as they leave the magnet. Which pole of the magnet did you always start at? Magnetic field lines begin at a magnet’s north pole and end at the south pole. The lines are close together where the field is strong. The lines get farther apart as the field gets weaker. The magnetic field is strongest close to the magnetic poles. It gets weaker farther away from the poles. Field lines that curve toward each other show attraction. Field lines that curve away from each other show repulsion. 156 Lesson EE What is magnetism? Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. What is a magnetic field? How are magnetic fields made? A moving electric charge produces a magnetic field. All atoms have negatively charged particles called electrons. These electrons spin around the nucleus of an atom. Each electron produces a magnetic field because of how it moves. The electrons in atoms that make up magnets are like even smaller magnets. The magnetic fields of many of the atoms in iron and other materials point in the same direction. A group of atoms with their magnetic fields pointing in the same direction is called a magnetic domain. 4. Identify Do the magnetic fields in a magnetic domain all point in the same direction or in different directions? How can some materials become magnetized? A material, like iron or steel, that can become magnetized has many magnetic domains. When the material is not magnetized, these magnetic domains point in all directions as shown in the figure below. The material does not act like a magnet. This is because the magnetic fields made by the domains cancel each other out. Picture This 5. Explain How do you Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. know that the material in this picture is not magnetized? A magnet has a large number of magnetic domains that are lined up and pointing in the same direction. Suppose you hold a strong magnet next to a piece of iron. The magnet causes the magnetic field in many of the magnetic domains in the iron to line up with the magnet’s field, as in the figure below. The magnetic fields of the iron’s magnetic domains are added together. This magnetizes the iron. Picture This 6. Label Which pole of the bar magnet on the right should be closest to the figure on the left? Label this pole of the bar magnet N for north or S for south. South Carolina Science Essentials 157 Earth’s Magnetic Field Bar magnets are not the only objects that have magnetism. Earth has a magnetic field, too. The space affected by Earth’s magnetic field is the magnetosphere (mag NEE tuh sfihr). The magnetosphere repels most of the charged particles from the Sun. Earth’s magnetic field probably comes from deep within Earth’s core. Moving melted iron in the outer core might produce the magnetic field. The shape of Earth’s magnetic field is like the magnetic field of a huge bar magnet. 7. Explain How does Earth’s magnetosphere protect Earth from charged particles from the Sun? What are magnets found in nature? Some animals, including honeybees, rainbow trout, and homing pigeons, use magnetism to find their way. They have tiny pieces of magnetite in their bodies. These pieces are so small that they might contain only one magnetic domain. Scientists have shown that some animals use these natural magnets to find Earth’s magnetic field. They use Earth’s magnetic field and the position of the Sun or stars to help them find their way. Earth’s magnetic poles do not stay in one place. The magnetic pole in the north today is in a different place than it was 20 years ago. Sometimes, Earth’s magnetic field also changes direction. For example, a compass needle that pointed south 700 thousand years ago would point north today. During the last 20 million years, Earth’s magnetic field has changed direction more than 70 times. The magnetism of old rocks shows these changes in the magnetic field. When some kinds of molten rock cool, magnetic domains of iron in the rock line up with Earth’s magnetic field. After the rock cools, the domains are frozen in place. So, the old rocks show the direction of Earth’s magnetic field as it was long ago. What is a compass needle? 8. Infer If Earth’s magnetic field is like a bar magnet, where is the north pole of the bar magnet? 158 Lesson EE What is magnetism? A compass needle is a small bar magnet. It has a north and a south magnetic pole. When a compass is in a magnetic field, the needle turns until it lines up with the magnetic field line at its location. Earth’s magnetic field also makes a compass needle turn. The north pole of the compass needle points toward Earth’s magnetic pole that is in the north which is actually a magnetic south pole. Earth’s magnetic field is like that of a bar magnet with the south pole near Earth’s north pole. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. How does Earth’s magnetic field change? After You Read Mini Glossary magnetic domain: a group of atoms with their magnetic fields pointing in the same direction magnetic field: the space around a magnet where the magnetic force is magnetosphere: the space affected by Earth’s magnetic field 1. Review the terms and their definitions in the Mini Glossary above. Circle two of the terms. On the lines below, tell how these two terms are related. 2. Complete the flowchart below to describe how the magnetic domains of a paper clip change as it becomes magnetized. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. A strong magnet is Magnetic domains Magnetic domains point in all directions. . Magnetic fields add together. . . 3. You were asked to make an outline of the lesson. How can you use the outline to help you study for a quiz? Visit msscience.com to access your textbook, interactive games, and projects to help you learn more about magnetism. End of Lesson South Carolina Science Essentials 159 Llesson 3 FF Heat Standard 6-5.5: Illustrate the directional transfer of heat energy through convection, radiation, and conduction. compare thermal energy and heat ■ three ways heat moves ■ what insulators and conductors are ■ Identify Main Ideas As you read this lesson, highlight the main ideas about conduction, radiation, and convection. Find Main Ideas Add the label “Heat” to the right column of Foldable A as shown below. As you read this lesson, write down the main ideas about heat. 160 Lesson FF Heat Before You Read Write down two things you do to make yourself feel warmer. Read to Learn Heat and Thermal Energy It’s cold, turn up the heat. Heat the oven to 375°F. A heat wave has hit the Midwest. You’ve often heard the word heat, but what exactly is it? Heat is thermal energy that moves from one object to another when the objects are at different temperatures. Heat moves, or is transferred, when two objects are in contact with each other. More heat is transferred when the difference in temperature between the objects is large. Less heat is transferred when the temperature difference is small. For example, no heat moves between two pots of boiling water that are touching. The water in both pots is the same temperature. Suppose a pot of boiling water touches a pot of cold water. Heat is transferred from the hot pot to the cold pot. The hot water loses heat and the cold water gains heat. Heat will transfer until both objects are the same temperature. How does heat move? Heat always is transferred from warmer objects to cooler objects. It never transfers from a cooler object to a warmer one. The warmer object loses thermal energy. It becomes cooler. The cooler object gains thermal energy. It becomes warmer. Heat can be transferred in three ways––by conduction, radiation, or convection. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. What You’ll Learn Conduction When you eat something hot, conduction occurs. As the hot food touches your mouth, heat moves from the food to your mouth. Conduction is the movement of heat between objects that are touching. When you hold an ice cube in your hand, conduction is occurring. The ice cube starts to melt and your hand starts to feel cold. The fast-moving molecules in your warm hand bump into the slow-moving molecules in the cold ice. When the faster-moving molecules touch the slower-moving molecules, energy passes from molecule to molecule. As a result, heat moves from your warm hand to the cold ice. The slow-moving molecules in the ice start moving faster. With more energy, the ice warms and its temperature rises. The ice begins to melt. The fast-moving molecules in your hand move more slowly. They lose thermal energy and your hand becomes cooler. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. When does conduction work best? Conduction works best in solids and liquids. That’s because the molecules and atoms are closer together in a solid or a liquid than in a gas. The molecules and atoms have to move only a short distance before they bump into each other and transfer energy to another molecule or atom. So, heat is transferred by conduction faster in liquids and solids than in gases. 1. Describe Give an example of heat being transferred by conduction. 2. Explain What transfers thermal energy when objects are heated by radiation? Radiation On a beautiful, clear day, you walk outside and notice the warmth of the Sun. How does the Sun heat Earth? The Sun transfers thermal energy to Earth, but not by conduction. The Sun and Earth do not touch. Instead, the Sun transfers heat to Earth by radiation. Radiation is the transter of energy by electro-magnetic waves. Electromagnetic waves can carry energy through empty space, like the space between Earth and the Sun. These waves can also carry energy through solids, liquids, and gases. The Sun is not the only object that transfers heat by radiation. Sit next to a fire in a fireplace. You feel heat transferred by radiation from the fire to your skin. All objects give off electromagnetic radiation. Warm objects give off more radiation than cool objects. South Carolina Science Essentials 161 Convection When you heat a pot of water, heat transfers by conduction from the stove to the pot. Heat can be transferred in another way, too. As gas and liquid molecules move, they carry energy with them. Convection is the transfer of thermal energy through the movement of molecules from one part of a material to another. How is heat transferred by convection? 3. Explain Why is a warm fluid less dense than a cool fluid? Heat is transferred by convection as a pot of water is heated. First, thermal energy is transferred to the water molecules near the bottom of the pot. These water molecules begin to move faster as their thermal energy increases. The faster the molecules move, the farther apart they get. Now the molecules in the warm water are farther apart than the molecules in the cooler water near the top of the pot. So, the warm water is less dense than the cool water. The warm, less dense water rises to the top of the pot. The cool, more dense water moves down to the bottom of the pot. As the cool water is heated, it rises to the top. This repeats until all the water in the pot is the same temperature. Picture This 4. Natural convection takes place when a cool, dense fluid, pushes away a warm, less dense fluid. Think of the shore of a lake. The water is cooler than the land during the day. The warm land heats the air above it by conduction. As the air gets hotter, its particles move faster and farther away from each other. The hot air is less dense and it rises. The cooler, denser air from above the lake moves toward the land. You feel this movement of cool air as wind. The figure shows that as cool air moves over the land, it pushes the warm, less dense air up. The land heats the cool air and the cycle repeats. Describe Using a Warm air highlighter, make one long stroke that follows the arrows in the figure to show the path of the air flow. Describe the movement of the air. Cool air 162 Lesson FF Heat Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. What is natural convection? What is forced convection? Forced convection takes place when an outside force pushes a fluid to make the fluid move and transfer heat. A fan is an example of an outside force. Computers use fans to keep their electronic parts from getting too hot. The fan blows cool air onto the hot parts. Heat from the computer parts is transferred to the air around them by conduction. Warm air is pushed up and away from the hot parts and cool air moves in. The hot parts keep transferring heat to the cool air around them. Make Lists Make a Foldable like the one below. List materials that are thermal conductors and materials that are thermal insulators. T Therm Conductors o Thermal Insulators Thermal Conductors Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Why are most cooking pans made of metal? Why does a metal spoon in a bowl of hot soup feel warm? Metal is a good conductor of heat. A conductor is any material that transfers heat easily. Some materials are good conductors because of the types of atoms or chemical compounds they are made up of. Remember that an atom has a nucleus surrounded by one or more electrons. In some materials, like metals, these electrons are not held tightly in place. They can move around freely. These electrons can transfer thermal energy by bumping into other atoms. Metals such as gold and copper are the best conductors of heat. Thermal Insulators When you cook food in a pan, you want the pan to conduct heat from the hot burner to your food. But you do not want heat to move easily to the pan’s handle. An insulator is a material that heat does not flow through easily. Most cooking pans have handles made from insulators. Liquids and gases are usually better insulators than solids are. Air is a good insulator. Many insulating materials have spaces filled with air. The air prevents heat from moving through the material by conduction. Metals and other good conductors of heat are poor insulators. Air and other good insulators are poor heat conductors. Houses and other buildings contain insulating materials. These materials reduce the heat conduction between the inside and outside. Insulating windows are made of two layers of glass. There is a layer of air or other gas in between the layers of glass. The layer of air reduces heat conduction. It keeps heat from going outside in the winter and from coming inside in the summer. 5. Determine Would a container made of a conductor or of an insulator be better for keeping hot food from getting cold? South Carolina Science Essentials 163 Heat Absorption On a hot day, you can walk barefoot across the lawn. But the pavement of the street is too hot to walk on. Why is the pavement hotter than the grass? The change in temperature of an object as it absorbs heat depends on the material it is made of. What is specific heat? 6. Explain Which kind of material needs more heat to raise its temperature, one with a high specific heat or one with a low specific heat? The specific heat of a material is the amount of heat needed to raise 1 kilogram of that material by 1°C. More heat is needed to change the temperature of a material with a high specific heat than a material with a low specific heat. For example, the sand on a beach has a lower specific heat than water in a lake. On a hot summer day, the sand feels warmer than the water. Both are warmed by radiation from the Sun. But, the sand heats up faster than the water because it has a lower specific heat than the water. At night, the sand feels cool and the water feels warmer. They both lose thermal energy to the cooler night air. However, the temperature of the sand decreases faster than the temperature of the water. Some power plants and factories use water to cool hot equipment. The cooling water becomes hot. This hot water may be released into lakes, rivers, or the ocean. The hot water increases the temperature of the nearby water. Thermal pollution is the increase in the temperature of a body of water caused by warmer water being added to it. Rainwater falling on warm roads and parking lots can also cause thermal pollution. 7. Identify Name one harmful result of thermal pollution. 164 Lesson FF Heat Why is thermal pollution harmful? Warmer water has less dissolved oxygen than cooler water. Warm water causes fish and other animals to use more oxygen. Some animals may die because there is not enough oxygen in the water. Also, in warmer water, parasites and diseases are a bigger problem for many organisms. Factories and power plants can reduce thermal pollution by cooling hot water in cooling towers before it’s released. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Thermal Pollution After You Read Mini Glossary conduction: the movement of heat between objects that are touching conductor: any material that transfers heat easily convection: the transfer of thermal energy through the movement of molecules from one part of a material to another heat: thermal energy that moves from one object to another when the objects are at different temperatures radiation: the transfer of energy by electromagnetic waves specific heat: the amount of heat needed to raise 1 kilogram of a material by 1°C thermal pollution: the increase in the temperature of a body of water caused by adding warmer water 1. Review the terms and definitions in the Mini Glossary. Chose one of the terms that describes how heat can be moved and use it in a sentence. 2. Fill in the blanks on the web diagram below with examples of the different methods of heat transfer. Conduction Example: Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Convection Heat Transfer Example: Radiation Example: 3. You were asked to highlight the main ideas about conduction, radiation, and convection. What would be another way to learn about these three methods of heat movement? Visit msscience.com to access your textbook, interactive games, and projects to help you learn more about heat. End of Lesson South Carolina Science Essentials 165 Llesson GG 3 Work and Power Standard 6-5.6: Recognize that energy is the ability to do work (force exerted over a distance). when work is done how to calculate how much work is done ■ how work and power are related ■ ■ Study Coach Make Flash Cards After you read each page, write two quiz questions on flash cards. Write a question on one side of each flash card. Write the answer on the other side. Quiz yourself until you know the answers. Before You Read Describe the work you have done today. Read to Learn What is work? In science, there is a special definition of work. Work is done when a force makes an object move in the same direction as the force that is applied. You do work when you lift your books, turn a doorknob, or write with a pen. What does motion have to do with work? Suppose your teacher asks you to move a box of books. You try, but the box will not move. It is too heavy. You are tired because you tried to force the box to move. But you have not done any work. Two things must happen for you to do work. First, you must apply a force on an object. Second, the object must move in the same direction as the force that you applied. Imagine a girl standing still and holding two bags of groceries. Is she doing work? No, she is not moving or causing anything to move. How does the direction of force affect work? Organize Information Make the following Foldable to help you understand work and power. What is work? 166 What is power? Lesson GG Work and Power Your arms apply a force upward when you lift a basket of clothes. Your arms have done work because the basket moved in the same direction as the force applied by your arms. If you walk forward with the basket, your arms are still applying an upward force on the basket. But you and the basket are moving forward. The basket is not moving in the same direction as the upward force applied by your arms. So, no work is done by your arms. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. What You’ll Learn Does all of a force do work? Sometimes only part of a force moves an object. Think about what happens when you push a lawn mower. Look at the figure. You push at an angle to the ground. Part of the force is forward. Part of the force is downward. Which part of the force does work? Only the part of the force that is forward does work. It is in the same direction as the motion of the mower. Picture This 1. Identify Which force in the figure does work? Circle the label and arrow. Forward force Total force Downward Force Motion Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Applying Math 2. Calculate A woman lifted a box with a force of 50 N. She lifted the box 2 m. How much work did she do? Show your work. 3. Infer Suppose the woman Calculating Work Work is done when a force makes an object move. More work is done if the force is increased or if the object moves farther. You can calculate how much work is done by using the work equation below. The SI unit for work is the joule (JEWL). The joule is named for the nineteenth-century scientist James Prescott Joule. work (joules) force (newtons) distance (meters) W Fd What distance is used for the work equation? Suppose you give a book a push and it slides across a table. You use the distance an object moves while a force is acting on it to calculate work, not the total distance the object moved. So, the distance in the work equation is the distance the book moved while you were pushing it. in Problem 2 above lifted the box only 1 m. What happens to the amount of work done? South Carolina Science Essentials 167 What is power? What does it mean to be powerful? Imagine two weightlifters lifting the same amount of weight. They lift the weight the same distance above the floor. They both do the same amount of work. But the amount of power they use depends on how long it took to do the work. Power is how quickly work is done. The weightlifter who lifted the weight in less time is more powerful. How do you calculate power? You can calculate power by dividing the amount of work done by the time needed to do the work. Applying Math 4. Calculate A teacher does 140 J of work in 20 s. How much power in watts did he use? Show your work. work (joules) time (seconds) W P t power (watts) The SI unit of power is the watt. The watt is named for James Watt, a nineteenth-century British scientist. Remember that when something moves, it has kinetic energy. If you push a chair and make it move, you do work on the chair. You also change the chair’s energy. By making the chair move, you increase the chair’s kinetic energy. If you lift an object higher, you also change the energy of the object. The potential energy of an object increases when it is higher above Earth’s surface. When you lift an object, you do work on the object and increase its potential energy. 5. Summarize When you do work on an object, what two kinds of energy can you increase for the object? 168 Lesson GG Work and Power How are power and energy related? You increase the energy of an object when you do work on it. Energy cannot be created or destroyed. If the object gains energy, you must lose energy. When you do work on an object, you move, or transfer, energy to the object and your energy decreases. The amount of work done is the amount of energy transferred to the object. So, power is also equal to the amount of energy transferred in a certain amount of time. Sometimes energy can be transferred even when no work is done. This happens when heat flows from a warm object to a cold one. Energy can be transferred in many ways, even when no work is done. Power is always the rate, or speed, at which energy is transferred. The rate is the amount of energy transferred divided by the time needed to transfer it. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. How can doing work change energy? After You Read Mini Glossary power: how quickly work is done work: is done when a force makes an object move in the same direction as the force that is applied 1. Read the key terms and definitions in the Mini Glossary above. Describe work in your own words. 2. Complete the table. Action Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Lifting your books from the bottom of your locker Was work done on the book? In which direction was work done? How did the action change the energy of the object? yes up The books now have potential energy. Carrying your books from your locker to class Pushing your book across your desk for a friend to see 3. You were asked to make two flash cards for every page of the lesson. How did this help you learn the material in the lesson? Visit msscience.com to access your textbook, interactive games, and projects to help you learn more about work. End of Lesson South Carolina Science Essentials 169 Llesson 3 HH Using Machines Standard 6-5.6: Recognize that energy is the ability to do work (force exerted over a distance). What You’ll Learn how a machine makes work easier ■ about mechanical advantage and efficiency ■ how friction reduces efficiency ■ Locate Information Look at the lesson headings. Highlight each question head as you read. Then, use a different color to highlight the answers to the questions. Before You Read Describe a machine you used today and what it does. Read to Learn What is a machine? Scissors, brooms, and knives are all machines. A machine is a device that makes doing work easier. Organize Information Make the following Foldable to help you organize information about machines, mechanical advantage, and efficiency. What is a machine? What is mechanical advantage? What is efficiency? 170 Lesson HH Using Machines Machines change the way you do work. When you use a machine, you apply a force over a distance. You use force to move a rake. The force that you apply on a machine is input force. The work you do on a machine is equal to the input force times the distance over which your force moves the machine. The work that you do on the machine is the input work. The machine also does work. It applies a force to move an object over a certain distance. A rake applies a force to move leaves. Sometimes this force is called the resistance force. This means the machine must overcome some resistance. The force that the machine applies is output force. The work that the machine does is the output work. The output work can never be greater than the input work when you use a machine. So why use a machine? A machine can make work easier in three ways because it can: • change the amount of force you need to apply. • change the distance over which the force is applied. • change the direction in which the force is applied. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Mechanical Advantage How does changing force make work easier? Some machines make work easier by reducing the force you need to apply. You need less force to do the work. This kind of machine increases the input force so the output force is greater than the input force. The number of times that a machine increases the input force is the mechanical advantage (MA) of the machine. You can calculate mechanical advantage using this equation: Applying Math 1. output force (newtons) input force (newtons) F MA out Fin mechanical advantage How does changing distance make work easier? Some machines let you apply force over a shorter distance. In these machines, the output force is less than the input force. A rake is an example of this kind of machine. You move your hands a small distance at the top of the handle. But, the bottom of the rake moves a greater distance. The mechanical advantage of this kind of machine is less than 1. This is because the output force is less than the input force. Calculate Suppose you use a machine to move a large rock. You apply a force of 100 N to the machine. The machine applies a force of 2,000 N to the rock. What is the mechanical advantage of the machine? Circle your answer. a. 2 b. 10 c. 20 d. 100 Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. How does changing direction make work easier? Sometimes it is easier to apply a force in a certain direction. Imagine putting a flag up on a flagpole. It is easier to pull down on the rope on the flagpole than to pull up on it. Some machines let you change the direction of the input force. In these machines, the distance and the force do not change. The mechanical advantage of this kind of machine is equal to 1. The output force is equal to the input force. The figures show the three ways machines make doing work easier. Input force Input force Input force Increases force Increases distance Changes direction of force Larger force applied over a shorter distance Smaller force applied over a longer distance Force applied over same distance in a different direction Picture This 2. Describe Write the words that make the sentence true on the lines below: When a machine increases a. , it is applied over a shorter b. . a. _______________________ b. _______________________ South Carolina Science Essentials 171 Efficiency Applying Math 3. Calculate Workers use a ramp to load a piano into a truck. The output work, or the amount of work needed to move the piano, is 12,000 J. The workers do 15,000 J of work. What is the efficiency of the ramp? Show your work. A machine does not increase the input work. For a real machine, the output work done by the machine is always less than the input work that is done on the machine. There is friction when parts of the machine move. Friction changes some of the input work into heat. So, the output work is less. If friction in the machine decreases, the efficiency, or amount of effort, of the machine increases. The efficiency of a machine is the ratio of the output work to the input work. You can find efficiency by using this equation: output work (joules) 100% input work (joules) W eff out 100% Win efficiency (in percent) 4. Identify What causes friction? Imagine pushing a heavy box up a ramp. The bottom surface of the box slides across the top surface of the ramp. Neither the box nor the ramp is perfectly smooth. Each surface has high spots and low spots. As the two surfaces slide past each other, high spots on the two surfaces touch each other. The places that they touch are called contact points. At these contact points, atoms and molecules can bond together. This makes the contact points stick together. The attractive forces between all of the bonds added together is the frictional force. The frictional force tries to keep the two surfaces from sliding past each other. To keep the box moving, a force must be applied. The force has to break the bonds between the contact points. Even after these bonds are broken and the box moves, new bonds form as different parts of the two surfaces touch. How can friction be reduced? 5. Evaluate Which will have more friction, two pieces of sandpaper or two pieces of notebook paper? 172 Lesson HH Using Machines One way to reduce friction between two surfaces is to add oil to the surfaces. Oil can fill the gaps between the surfaces. Oil keeps many of the high spots from touching each other. There are fewer contact points between the surfaces. So, the force of friction is less. This means more of the input work is changed to output work by the machine. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. How does friction affect a machine? After You Read Mini Glossary efficiency: the ratio of the output work to the input work input force: the force that you apply on a machine mechanical advantage: the number of times that a machine increases the input force output force: the force that a machine applies 1. Review the terms and their definitions in the Mini Glossary. Describe how the input force and output force of a machine work together to make work easier. 2. In the figure below, write the way each machine can be useful. Write the terms increases force, changes direction of force, and increases distance in the correct locations. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. How Machines Make Work Easier Input force Force applied over same distance in a different direction Input force Smaller force applied over a longer distance Input force Larger force applied over a shorter distance 3. How did highlighting the answers to the headings that were questions help you make sure you understood the material in the lesson? Visit msscience.com to access your textbook, interactive games, and projects to help you learn more about using machines. End of Lesson South Carolina Science Essentials 173 Simple Machines Llesson I3I Standard 6-5.6: Recognize that energy is the ability to do work (force exerted over a distance). Standard 6-5.7: Explain how the design of simple machines (including levers, pulleys, and inclined planes) helps reduce the amount of force required to do work. Standard 6-5.8: Illustrate ways that simple machines exist in common tools and complex machines. What You’ll Learn what the different simple machines are ■ how to find the mechanical advantage of each simple machine ■ Before You Read Suppose you need to put a heavy box into a truck. Would you rather push the box up a ramp or lift it straight into the air? Explain. Read to Learn through this lesson, underline each kind of simple machine. Compare and Contrast Make the following Foldable to help you compare and contrast simple and compound machines. Simple Machines Both Compound Machines 174 Lesson II Simple Machines What is a simple machine? In the last lesson you learned that machines make work easier. Some machines like cars, elevators, or computers are very complicated. But machines can be very simple. A hammer, a shovel, and a ramp are all machines. A simple machine is a machine that does work with only one movement. There are six simple machines: an inclined plane, a lever, a wheel and axle, a screw, a wedge, and a pulley. A compound machine is a machine made up of more than one simple machine. A bicycle is a compound machine. Inclined Plane Ramps have been used for thousands of years. Ancient Egyptians might have used them to build the pyramids. Archaeologists hypothesize that the Egyptians built huge ramps to move limestone blocks. The blocks each weighed more than 1,000 kg. A ramp is a simple machine known as an inclined plane. An inclined plane is a flat, sloped surface. You might need a lot of force if you have to lift an object. An inclined plane lets you use less force to move an object from one height to another. The longer an inclined plane is, the less force is needed to move the object. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Identify Simple Machines As you read Weight = 1,500 N Force = 300 N 1m How are inclined planes used? Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. 5m Force = 1,500 N Suppose you have to lift a box weighing 1,500 N into the back of the truck that is 1 m off the ground. Could you do that? The force (1,500 N) times the distance (1 m) equals 1,500 J of work. Look at the figure. Suppose you use a 5-m-long ramp to lift the box into the truck. The amount of work you need to do does not change. You still need to do 1,500 J of work. But, the distance over which you apply the force is now 5 m. You can find the force you need by dividing both sides of the work equation by distance. Picture This 1. Evaluate Circle the force needed to push the box up the ramp. Then, circle the force needed to lift the box straight up. How much more force is needed to lift the box straight up? work (joules) distance (meters) 1,500 J Force 300 N 5m Force When you use the ramp, you need to apply a force of only 300 N. A force of 300 N is much less than a force of 1,500 N. With the ramp, you apply the force over a distance that is five times longer. So, the force is five times less. The mechanical advantage of an inclined plane is the length of the inclined plane divided by its height. In this example, the ramp has a mechanical advantage of 5. Applying Math 2. Calculate You need to lift a different box into the truck. The amount of work it takes is 1,000 J. You use a 2 m ramp. How much force do you need? Show your work. What is a wedge? A wedge is an inclined plane that moves. A wedge can have one or two sloping sides. A knife is an example of a wedge. An axe and certain kinds of doorstops also are wedges. The mechanical advantage of a wedge increases as it becomes longer and thinner. South Carolina Science Essentials 175 Are there wedges in your body? You have wedges in your body. Think of biting into an apple. The bite marks on the apple show that your front teeth are wedge shaped. A wedge changes the direction of the applied force. The downward force of your bite is changed into a sideways force. The sideways force pushes the skin of the apple apart. What is a screw? 3. Explain What holds a screw into an object? The screw is another form of inclined plane. A screw is an inclined plane wrapped around a cylinder or post. The inclined plane on a screw forms the threads of the screw. A screw changes the direction of the applied force. The applied force pulls the screw into the material. Friction between the threads and the material holds the screw tightly in place. The mechanical advantage of the screw is the length of the inclined plane wrapped around the screw divided by the length of the screw. The more tightly wrapped the threads are, the easier it is to turn the screw. A lever is any stiff rod or plank that turns around a point. The point that the lever turns around is called a fulcrum. You can find the mechanical advantage of a lever by dividing the distance from the input force to the fulcrum by the distance from the fulcrum to the output force. This is shown in the figure. Picture This 4. Calculate Use the figure. Suppose the distance from the input force to the fulcrum is 60 cm. The distance from the fulcrum to the output force is 20 cm. What is the mechanical advantage? Show your work. Input force Output force Mechanical 10 cm 1 = = advantage 50 cm 5 10 cm 50 cm Input force Output force Mechanical 50 cm = = 5 advantage 10 cm 50 cm 10 cm The fulcrum of a lever can be in different positions. When the fulcrum is closer to the output force than the input force, the mechanical advantage is greater than 1. Scissors, a wheelbarrow, and a baseball bat are all levers. 176 Lesson II Simple Machines Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Lever Wheel and Axle Imagine a doorknob the size of a pencil. Would it be easy to turn? No, it would be hard to turn. A doorknob is a simple machine that makes opening a door easier. A doorknob is a wheel and axle. A wheel and axle is made up of two round objects of different sizes that are attached so they turn together. The larger object is the wheel and the smaller object is the axle. The faucet handle shown in the figure is a wheel and axle. Picture This Wheel 5. Axle Analyze Does the wheel or the axle of the faucet make the output force? Input force Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Output force How do you find the MA of a wheel and axle? The MA (mechanical advantage) of a wheel and axle is usually greater than 1. You find it by dividing the radius of the wheel by the radius of the axle. Suppose the radius of the wheel is 12 cm and the radius of the axle is 4 cm. The mechanical advantage is 3. Applying Math 6. Calculate A wheel has a radius of 15 cm. The axle has a radius of 3 cm. What is the mechanical advantage of the wheel and axle? Show your work. How are wheels and axles used? In some wheels and axles, the input force turns the wheel. The wheel turns the axle. The turning axle makes the output force. The mechanical advantage is greater than 1 because the wheel is bigger than the axle. This means the output force is greater than the input force. A doorknob, a steering wheel, and a screwdriver are examples of this kind of wheel and axle. In other wheels and axles, the input force turns the axle. The axle turns the wheel. The wheel makes the output force. The mechanical advantage is less than 1. The output force is less than the input force. A fan and a Ferris wheel are examples of this kind of wheel and axle. South Carolina Science Essentials 177 Pulley To raise a sail, a sailor pulls down on a rope. The rope uses a simple machine called a pulley to change the direction of the force needed. A pulley is a grooved wheel with a rope or cable wrapped over it. What is a fixed pulley? 7. Describe How does a pulley change the force you apply? Think about the pulley on a sail. The pulley is attached to something above your head. This kind of pulley is called a fixed pulley. When you pull down on the rope, the sail is pulled up. Look at the figure of the fixed pulley below. A fixed pulley does not change the force you apply. It also does not change the distance over which you apply a force. A fixed pulley does change the direction in which you apply your force. The mechanical advantage of a fixed pulley is 1. Picture This 8. Explain How does a movable pulley change the input force? A fixed pulley changes the direction of the input force. Fixed pulley 178 Lesson II Simple Machines You can also attach a pulley to the object you need to lift. This is called a movable pulley. A movable pulley lets you apply a smaller force to lift the object. The mechanical advantage of a movable pulley is always 2. The middle pulley in the figure below is a movable pulley. You often will see movable and fixed pulleys used together. This is called a pulley system. The mechanical advantage of a pulley system is equal to the number of sections of rope pulling up on the object. The mechanical advantage for the pulley system in the figure is 3. A movable pulley multiplies the input force. Movable pulley A pulley system uses more than one pulley to increase the mechanical advantage. Pulley system Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. What is a movable pulley? After You Read Mini Glossary compound machine: a machine made up of more than one simple machine inclined plane: a flat, sloped surface lever: any stiff rod or plank that turns around a point pulley: a grooved wheel with a rope or cable wrapped over it screw: an inclined plane wrapped around a cylinder or post simple machine: a machine that does work with only one movement wedge: an inclined plane that moves wheel and axle: two round objects of different sizes that are attached so they turn together 1. Review the terms and their definitions in the Mini Glossary. Write a sentence describing how a screw and a wedge are related. 2. Match each simple machines with the correct example. Write the letter of each simple machine in Column 2 on the line in front of the example it is or uses in Column 1. Copyright © Glencoe/McGraw-Hill, a division of The McGraw-Hill Companies, Inc. Column 1 Column 2 1. tooth a. inclined plane 2. doorknob b. wheel and axle 3. threads of a lightbulb c. wedge 4. wheelbarrow d. screw 5. ramp e. pulley 6. flagpole rope f. lever 3. What would be a good way to teach an elementary science class about simple machines? Visit msscience.com to access your textbook, interactive games, and projects to help you learn more about simple machines. End of Lesson South Carolina Science Essentials 179