Botany
... • Are dependant on water for reproduction but can survive on land without drying out (as long as they have a fairly moist environment). • Alternate between sexual and asexual ...
... • Are dependant on water for reproduction but can survive on land without drying out (as long as they have a fairly moist environment). • Alternate between sexual and asexual ...
Topic 16 specification content - A
... I can explain that optical isomers (enantiomers) exist as non-superimposable mirror images and that they differ in their effect on plane polarised light ...
... I can explain that optical isomers (enantiomers) exist as non-superimposable mirror images and that they differ in their effect on plane polarised light ...
Ecology - Wappingers Central School
... • Autotrophs are also called producer organisms • Producer: capture solar energy to make sugars in the process of photosynthesis. Autotroph = producer = photosynthesis Producers are the first step in the food chain. They make the energy of the sun usable to other organisms. Without producers, all li ...
... • Autotrophs are also called producer organisms • Producer: capture solar energy to make sugars in the process of photosynthesis. Autotroph = producer = photosynthesis Producers are the first step in the food chain. They make the energy of the sun usable to other organisms. Without producers, all li ...
1. Substrate level phosphorylation A) is part
... A) changes the muscles to a more type II fiber character B) changes muscles to a more type I fiber character C) makes mice more prone to obesity because they use more lipid as fuel D) both B and C ...
... A) changes the muscles to a more type II fiber character B) changes muscles to a more type I fiber character C) makes mice more prone to obesity because they use more lipid as fuel D) both B and C ...
Nine Week Review Notes. Everything you need to know about cells
... Chemical in chloroplast that absorbs energy from sun for photosynthesis. Makes plants green . To remember the difference you can think. ChloroPHYLL fills the chloroplast The plant takes in carbon dioxide and water and combines them to make glucose and oxygen. ...
... Chemical in chloroplast that absorbs energy from sun for photosynthesis. Makes plants green . To remember the difference you can think. ChloroPHYLL fills the chloroplast The plant takes in carbon dioxide and water and combines them to make glucose and oxygen. ...
Ecology Worksheet - Blue Valley Schools
... Concept 36.1 Feeding relationships determine the path of energy and chemicals in ecosystems. (pp. 788–791) Energy flow through ecosystems begins with producers. Producers are generally photosynthetic organisms such as plants that convert light energy from sunlight to the chemical energy of organic c ...
... Concept 36.1 Feeding relationships determine the path of energy and chemicals in ecosystems. (pp. 788–791) Energy flow through ecosystems begins with producers. Producers are generally photosynthetic organisms such as plants that convert light energy from sunlight to the chemical energy of organic c ...
5th Grade Ecosystem Common Assessment
... 5th Grade Science - Ecosystems Common Assessment 1. In the daylight, organisms that have chlorophyll, such as plants, algae, and some bacteria, can use the sun’s energy, water, and carbon dioxide to make their own food. What is this process called? A. B. C. D. ...
... 5th Grade Science - Ecosystems Common Assessment 1. In the daylight, organisms that have chlorophyll, such as plants, algae, and some bacteria, can use the sun’s energy, water, and carbon dioxide to make their own food. What is this process called? A. B. C. D. ...
CHAPTER 3 THE CHEMISTRY OF ORGANIC MOLECULES
... are also made of carbon, hydrogen, and oxygen, though not in the same fixed ratio. Fats and oils, also called triglycerides, allow long-term energy storage and are formed from the dehydration reaction between one glycerol and three fatty acids. Both glycerol and fatty acids have polar groups, but fa ...
... are also made of carbon, hydrogen, and oxygen, though not in the same fixed ratio. Fats and oils, also called triglycerides, allow long-term energy storage and are formed from the dehydration reaction between one glycerol and three fatty acids. Both glycerol and fatty acids have polar groups, but fa ...
Name ionic compounds containing main group or
... What is the formula mass of tin (II) perchlorate? How many hydrogen atoms would there be in 6 formula units of ammonium acetate? Which of the following is correct? (a) mass equals moles divided by molecular mass (b) moles times mass equals molecular weight (c) moles equals molecular mass times mass ...
... What is the formula mass of tin (II) perchlorate? How many hydrogen atoms would there be in 6 formula units of ammonium acetate? Which of the following is correct? (a) mass equals moles divided by molecular mass (b) moles times mass equals molecular weight (c) moles equals molecular mass times mass ...
Presentation
... 8. condensation, precipitation, surface water evaporation, transpiration water cycle 9. a gas form the atmosphere is changed into usable compounds by lightening or by bacteria, decomposing organic matter and animal wasted release those compounds into the soil, plants use the compounds to build cell ...
... 8. condensation, precipitation, surface water evaporation, transpiration water cycle 9. a gas form the atmosphere is changed into usable compounds by lightening or by bacteria, decomposing organic matter and animal wasted release those compounds into the soil, plants use the compounds to build cell ...
File
... Carbon dioxide is produced by cells as a by-product of aerobic cellular respirations Carbon dioxide accumulates in cells and diffuses from the cells into the interstitial fluid Under normal conditions the pressure of carbon dioxide PCO2 in the interstitial fluid is 5.6kPa The pressure gradient is la ...
... Carbon dioxide is produced by cells as a by-product of aerobic cellular respirations Carbon dioxide accumulates in cells and diffuses from the cells into the interstitial fluid Under normal conditions the pressure of carbon dioxide PCO2 in the interstitial fluid is 5.6kPa The pressure gradient is la ...
1 - TJ-Thomas
... 1. Who is considered the father of genetics? 2. What are Mendel’s 2 laws of inheritance? 3. How do Mendel’s 2 laws of inheritance relate to the meiosis? 4. What were Mendel’s experiments? 5. What are the names that Mendel gave to each of his generations? 6. How did Mendel explain his results? 7. Wha ...
... 1. Who is considered the father of genetics? 2. What are Mendel’s 2 laws of inheritance? 3. How do Mendel’s 2 laws of inheritance relate to the meiosis? 4. What were Mendel’s experiments? 5. What are the names that Mendel gave to each of his generations? 6. How did Mendel explain his results? 7. Wha ...
Carbon Chapter 5: The Large Biological Molecules
... What are the characteristics of carbon that make possible the building of such a wide variety of organic molecules? 1. Carbon has four valence electrons. It can form four different bonds with other carbon atoms or other atoms. 2. Carbon can form chains, branches, rings – a wide variety of shapes! ...
... What are the characteristics of carbon that make possible the building of such a wide variety of organic molecules? 1. Carbon has four valence electrons. It can form four different bonds with other carbon atoms or other atoms. 2. Carbon can form chains, branches, rings – a wide variety of shapes! ...
SG 7,8,9,10
... Describe 3 important monosaccharides. Describe 4 important disaccharides, what are monosaccharides involved, details about. Describe polysaccharides (glycans) in terms of oligosaccharides, homoglycans, heteroglycans, starches, glycogen. Describe glycoconjugates; proteoglycans, glycoproteins and func ...
... Describe 3 important monosaccharides. Describe 4 important disaccharides, what are monosaccharides involved, details about. Describe polysaccharides (glycans) in terms of oligosaccharides, homoglycans, heteroglycans, starches, glycogen. Describe glycoconjugates; proteoglycans, glycoproteins and func ...
marijuana horticulture
... stems and may need to be staked up, especially during flowering. Once the leaves expand, they start to manufacture food (carbohydrates). Chlorophyll (the substance that gives plants their green color) converts carbon dioxide (CO2) from the air, water, and light energy into carbohydrates and oxygen. ...
... stems and may need to be staked up, especially during flowering. Once the leaves expand, they start to manufacture food (carbohydrates). Chlorophyll (the substance that gives plants their green color) converts carbon dioxide (CO2) from the air, water, and light energy into carbohydrates and oxygen. ...
Cellular Respiration Study Guide NAME
... 1. NADH & FADH2 give up electrons to the electron transport chain. Protons are also given up by these molecules 2. The electrons are passed down the chain, losing energy at every exchange 3. The energy loss from moving electrons is used to pump protons between the inner & outer membranes forming con ...
... 1. NADH & FADH2 give up electrons to the electron transport chain. Protons are also given up by these molecules 2. The electrons are passed down the chain, losing energy at every exchange 3. The energy loss from moving electrons is used to pump protons between the inner & outer membranes forming con ...
The Molecules of Cells
... – Have characteristic functional groups – Many organic molecules important to living organisms are large macromolecules (polymers) composed of smaller subunits called monomers • Monomers are small organic molecules • Can either exist separately or can be bonded together into long chains to form poly ...
... – Have characteristic functional groups – Many organic molecules important to living organisms are large macromolecules (polymers) composed of smaller subunits called monomers • Monomers are small organic molecules • Can either exist separately or can be bonded together into long chains to form poly ...
Unit 2 Section 4
... such as those shown in Figure 3, are short-day plants. Chrysanthemums are also short-day plants. Other plants flower in spring or early summer, when night length is short. These plants are called long-day plants. Clover, spinach, and lettuce are examples of long-day plants. ...
... such as those shown in Figure 3, are short-day plants. Chrysanthemums are also short-day plants. Other plants flower in spring or early summer, when night length is short. These plants are called long-day plants. Clover, spinach, and lettuce are examples of long-day plants. ...
The_Respiratory_System_powerpoint3
... pressure inside your body to accommodate breathing. When your diaphragm pulls down, it not only leaves more space for the lungs to expand but also lowers the internal air pressure. Outside, where the air pressure is greater, you suck in air in an inhale. The air then expands your lungs like a pair o ...
... pressure inside your body to accommodate breathing. When your diaphragm pulls down, it not only leaves more space for the lungs to expand but also lowers the internal air pressure. Outside, where the air pressure is greater, you suck in air in an inhale. The air then expands your lungs like a pair o ...
Plant Parts
... multiples of three. Examples are grasses, orchids, lilies, and palms. Dicots have net-like veins, taproots, and flower parts in multiples of 4 or 5. Examples are columbine, roses, peas, sunflowers, oaks, and maples. ...
... multiples of three. Examples are grasses, orchids, lilies, and palms. Dicots have net-like veins, taproots, and flower parts in multiples of 4 or 5. Examples are columbine, roses, peas, sunflowers, oaks, and maples. ...
Notes - Pierce College
... hard time diffusing into the blood leading to high altitude sickness: nausea, dizziness, headache, shortness of breath. 4. Arterial pO2 in fingertip = same as pO2 in pulmonary vein! No O2 used up in transport! This used to determine how well lungs are exchanging O2! 5. Hemoglobin facilitates the tr ...
... hard time diffusing into the blood leading to high altitude sickness: nausea, dizziness, headache, shortness of breath. 4. Arterial pO2 in fingertip = same as pO2 in pulmonary vein! No O2 used up in transport! This used to determine how well lungs are exchanging O2! 5. Hemoglobin facilitates the tr ...
The Biology BitThese notes are just here to give
... Animals may have to find their own food, but plants make their own. They do this by taking in carbon dioxide from the air and water and minerals from the soil. The minerals are necessary for healthy growth in the same way that animals also need them. The water and carbon dioxide, however, are conver ...
... Animals may have to find their own food, but plants make their own. They do this by taking in carbon dioxide from the air and water and minerals from the soil. The minerals are necessary for healthy growth in the same way that animals also need them. The water and carbon dioxide, however, are conver ...
Care of Specialty Potted Plants
... poinsettias over to bloom again next year. The quality of home-grown plants seldom equals that of commercially grown plants. However, for those who wish to try, the following procedure can be followed. After the showy bracts fade or fall, set the plants where they will receive indirect light and tem ...
... poinsettias over to bloom again next year. The quality of home-grown plants seldom equals that of commercially grown plants. However, for those who wish to try, the following procedure can be followed. After the showy bracts fade or fall, set the plants where they will receive indirect light and tem ...
Photosynthesis
Photosynthesis is a process used by plants and other organisms to convert light energy, normally from the Sun, into chemical energy that can be later released to fuel the organisms' activities. This chemical energy is stored in carbohydrate molecules, such as sugars, which are synthesized from carbon dioxide and water – hence the name photosynthesis, from the Greek φῶς, phōs, ""light"", and σύνθεσις, synthesis, ""putting together"". In most cases, oxygen is also released as a waste product. Most plants, most algae, and cyanobacteria perform photosynthesis; such organisms are called photoautotrophs. Photosynthesis maintains atmospheric oxygen levels and supplies all of the organic compounds and most of the energy necessary for life on Earth.Although photosynthesis is performed differently by different species, the process always begins when energy from light is absorbed by proteins called reaction centres that contain green chlorophyll pigments. In plants, these proteins are held inside organelles called chloroplasts, which are most abundant in leaf cells, while in bacteria they are embedded in the plasma membrane. In these light-dependent reactions, some energy is used to strip electrons from suitable substances, such as water, producing oxygen gas. Furthermore, two further compounds are generated: reduced nicotinamide adenine dinucleotide phosphate (NADPH) and adenosine triphosphate (ATP), the ""energy currency"" of cells.In plants, algae and cyanobacteria, sugars are produced by a subsequent sequence of light-independent reactions called the Calvin cycle, but some bacteria use different mechanisms, such as the reverse Krebs cycle. In the Calvin cycle, atmospheric carbon dioxide is incorporated into already existing organic carbon compounds, such as ribulose bisphosphate (RuBP). Using the ATP and NADPH produced by the light-dependent reactions, the resulting compounds are then reduced and removed to form further carbohydrates, such as glucose.The first photosynthetic organisms probably evolved early in the evolutionary history of life and most likely used reducing agents, such as hydrogen or hydrogen sulfide, as sources of electrons, rather than water. Cyanobacteria appeared later; the excess oxygen they produced contributed to the oxygen catastrophe, which rendered the evolution of complex life possible. Today, the average rate of energy capture by photosynthesis globally is approximately 130 terawatts, which is about three times the current power consumption of human civilization.Photosynthetic organisms also convert around 100–115 thousand million metric tonnes of carbon into biomass per year.