Slide 1
... matter has particles in constant motion. The hotter the object then the faster the particles move. ...
... matter has particles in constant motion. The hotter the object then the faster the particles move. ...
Energy - Reocities
... Energy Energy defined as the capacity to do work, may exist in potential, kinetic, thermal, electrical, chemical, nuclear, or other various forms. There are, moreover, heat and work-i.e. energy in the process of transfer from one body to another. After it has been transferred, energy is always desig ...
... Energy Energy defined as the capacity to do work, may exist in potential, kinetic, thermal, electrical, chemical, nuclear, or other various forms. There are, moreover, heat and work-i.e. energy in the process of transfer from one body to another. After it has been transferred, energy is always desig ...
Forms of energy
... Fill in the blanks with the words at the bottom of the page. You can use words more than once. 1. Energy that is stored within an object is called ________ energy. 2. Compressed springs and stretched rubber bands store_________ energy. 3. The vibration and movements of the atoms and molecules within ...
... Fill in the blanks with the words at the bottom of the page. You can use words more than once. 1. Energy that is stored within an object is called ________ energy. 2. Compressed springs and stretched rubber bands store_________ energy. 3. The vibration and movements of the atoms and molecules within ...
Work and Energy PPT - Aurora City Schools
... d is the displacement is the angle between the force and the direction ...
... d is the displacement is the angle between the force and the direction ...
How is Work and Power Related? Chapter 5 Work and Power
... concept and calculations of Work Simple Machine- device that makes work easier multiply force OR distance Increasing force or distance are at the expense of the other variable Energy is conserved in an ideal situation no friction Work in would equal Work out in another words F x d (in) = F x d (out) ...
... concept and calculations of Work Simple Machine- device that makes work easier multiply force OR distance Increasing force or distance are at the expense of the other variable Energy is conserved in an ideal situation no friction Work in would equal Work out in another words F x d (in) = F x d (out) ...
Answers
... 2. In every energy transformation there are two outcomes: 1. ___work_________ is done and 2._heat_______ is given off. 3. In a battery ___chemical_______________ energy is changed to electrical energy. 4. In which substance (solids, liquids, gases) do particles move the slowest? solids_______ 5. In ...
... 2. In every energy transformation there are two outcomes: 1. ___work_________ is done and 2._heat_______ is given off. 3. In a battery ___chemical_______________ energy is changed to electrical energy. 4. In which substance (solids, liquids, gases) do particles move the slowest? solids_______ 5. In ...
Energy and energy resources
... Electrical- when the electrons in a wire ( or other substance) move back and forth. Sound- is the movement and vibrations of particles in the air, usually caused by movement. ( needs particles to work, there is no sound in space, so a space ship blowing up would actually be silent) Light- the ...
... Electrical- when the electrons in a wire ( or other substance) move back and forth. Sound- is the movement and vibrations of particles in the air, usually caused by movement. ( needs particles to work, there is no sound in space, so a space ship blowing up would actually be silent) Light- the ...
Energy Worksheet
... 1. Energy that is stored within an object is called ________ energy. 2. Compressed springs and stretched rubber bands store_________ energy. 3. The vibration and movements of the atoms and molecules within substances is called heat or ________ energy. 4. The energy stored in the centre of atoms is c ...
... 1. Energy that is stored within an object is called ________ energy. 2. Compressed springs and stretched rubber bands store_________ energy. 3. The vibration and movements of the atoms and molecules within substances is called heat or ________ energy. 4. The energy stored in the centre of atoms is c ...
Additional Energy Terms
... Name and describe different types of energy. • Potential: chemical, gravitational, elastic, nuclear, magnetic • Kinetic: motion, heat, electric, light, sound What can happen to energy? • Transfer or transformation. Always conserved. Heat energy: movement/vibration of molecules. Measured by temperatu ...
... Name and describe different types of energy. • Potential: chemical, gravitational, elastic, nuclear, magnetic • Kinetic: motion, heat, electric, light, sound What can happen to energy? • Transfer or transformation. Always conserved. Heat energy: movement/vibration of molecules. Measured by temperatu ...
Technology Chapter 27: Energy: The Foundation of Technology
... Biofuels: organic material that can be burned or converted into methane. Biogas: A mixture of methane and carbon dioxide produced by the bacterial decomposition of organic wastes and used as a fuel. Biomass: a type of resource having a living origin. Biotechnology: practices that improve propagation ...
... Biofuels: organic material that can be burned or converted into methane. Biogas: A mixture of methane and carbon dioxide produced by the bacterial decomposition of organic wastes and used as a fuel. Biomass: a type of resource having a living origin. Biotechnology: practices that improve propagation ...
Chapter 15
... given the objects mass and velocity Analyze how potential energy is related to an object’s position and give examples of gravitational and elastic potential energy Solve equations that relate an object’s gravitational potential energy to its mass and height Give examples of the major forms of energy ...
... given the objects mass and velocity Analyze how potential energy is related to an object’s position and give examples of gravitational and elastic potential energy Solve equations that relate an object’s gravitational potential energy to its mass and height Give examples of the major forms of energy ...
Mechanical Energy - Miss Burnett`s 6th grade Classroom
... 237 joules of potential energy, what is its mechanical energy? ...
... 237 joules of potential energy, what is its mechanical energy? ...
Energy - Office Mix
... Calculate Kinetic Energy Distinguish between kinetic energy and Potential energy • Classify different types of potential Energy • Calculate Potential energy associated with an object ...
... Calculate Kinetic Energy Distinguish between kinetic energy and Potential energy • Classify different types of potential Energy • Calculate Potential energy associated with an object ...
Energy Conversion Quiz Answer Key
... 10. Give an example of energy changing from one form to another. Answers may vary. Sample answer: Energy changes from chemical energy to mechanical energy when you digest food and use the energy it releases to move your body. ...
... 10. Give an example of energy changing from one form to another. Answers may vary. Sample answer: Energy changes from chemical energy to mechanical energy when you digest food and use the energy it releases to move your body. ...
Mr. Kelley`s 8th Grade Science – February
... Mr. Kelley’s 8th Grade Science – February-March Unit Plan Energy - The Cause of Motion (pp. 144-166 PH Science Explorer) See also: Assessment Study Guide found on pp. 166-173 Sub-unit Description ...
... Mr. Kelley’s 8th Grade Science – February-March Unit Plan Energy - The Cause of Motion (pp. 144-166 PH Science Explorer) See also: Assessment Study Guide found on pp. 166-173 Sub-unit Description ...
4 types of energy in physics: KE, PEg , PEs, Q
... What is its kinetic energy just as it reaches the ground? ...
... What is its kinetic energy just as it reaches the ground? ...
Law of Conservation of Energy
... the law of conservation of energy? A. An object always has the same amount of energy. B. Energy can change between many different forms, such as potential, kinetic, and thermal, but it is ultimately destroyed. C. The total quantity of energy in the universe never changes, it just changes forms. D. T ...
... the law of conservation of energy? A. An object always has the same amount of energy. B. Energy can change between many different forms, such as potential, kinetic, and thermal, but it is ultimately destroyed. C. The total quantity of energy in the universe never changes, it just changes forms. D. T ...
Energy Transformations
... 4 - Cite evidence to support the Law of Conservation of Energy. 3 - Investigate and describe the transformation of energy that occurs in given examples. 2 - Differentiate between kinetic and potential energy. 1 - Identify examples of kinetic and potential energy. ...
... 4 - Cite evidence to support the Law of Conservation of Energy. 3 - Investigate and describe the transformation of energy that occurs in given examples. 2 - Differentiate between kinetic and potential energy. 1 - Identify examples of kinetic and potential energy. ...
File
... 4. A 12-kg sled is moving at a speed of 5 m/s. At what speed will the sled have twice as much kinetic energy? 5. An object’s gravitational potential energy is directly related to… 6. Give three examples of objects with elastic potential energy. 7. A 3-kilogram cat is resting on top of a bookshelf th ...
... 4. A 12-kg sled is moving at a speed of 5 m/s. At what speed will the sled have twice as much kinetic energy? 5. An object’s gravitational potential energy is directly related to… 6. Give three examples of objects with elastic potential energy. 7. A 3-kilogram cat is resting on top of a bookshelf th ...
Unit 9 Test Review – Work and Energy
... Energy bar graphs/energy flow diagrams (Qualitative) o Identify types of energy present o Recognize energy transfer into/out of a system Conservation of energy calculations o Identify types of energy present (kinetic, GPE, EPE, chemical, thermal (Eint)) o Calculate how much of each type of energy is ...
... Energy bar graphs/energy flow diagrams (Qualitative) o Identify types of energy present o Recognize energy transfer into/out of a system Conservation of energy calculations o Identify types of energy present (kinetic, GPE, EPE, chemical, thermal (Eint)) o Calculate how much of each type of energy is ...
Energy in the Food Chain Handout
... Nuclear Energy: Stored in the nucleus of an atom and generated at nuclear power plants. Gravitational Energy: Stored in an object’s height. Ex: hydropower, moving objects down a hill ...
... Nuclear Energy: Stored in the nucleus of an atom and generated at nuclear power plants. Gravitational Energy: Stored in an object’s height. Ex: hydropower, moving objects down a hill ...
Energy Notes
... Energy - Ability to do work or cause change. Mechanical Energy - Energy an object has because of its motion or position. Potential Energy - Energy an object has because of its postion or shape. Kinetic Energy - Energy an object has because it is moving. Heat Energy - The energy related to the temper ...
... Energy - Ability to do work or cause change. Mechanical Energy - Energy an object has because of its motion or position. Potential Energy - Energy an object has because of its postion or shape. Kinetic Energy - Energy an object has because it is moving. Heat Energy - The energy related to the temper ...
William Flynn Martin
William Flynn Martin (born October 4, 1950) is an American energy economist, educator and international diplomat. Martin served as Special Assistant to President Reagan for National Security Affairs, Executive Secretary of the National Security Council in the West Wing of the White House and Deputy Secretary of the Department of Energy during the Ronald Reagan administration. He was President of the Council of the University for Peace, appointed to the Council by Secretary General of the United Nations Kofi Annan and served as the Executive Director of the Republican Platform Committee during the re-election bid of George H.W. Bush. He has held senior appointments and advisory positions under several Presidents including: Ronald Reagan, George H.W. Bush and George W. Bush.Martin was born in Tulsa, Oklahoma. He achieved his Bachelor of Science from the Wharton School of the University of Pennsylvania in 1972 and his Master of Science from MIT in 1974. His master's thesis was the basis of an article he co-authored with George Cabot Lodge in the March, 1975 Harvard Business Review entitled Our Society in 1985: Business May Not Like It [1].