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Explore the concept of energy, its various forms, conversions, and conservation. Learn the difference between kinetic and potential energy and understand how they are related to work. Discover other forms of energy such as thermal, chemical, electrical, sound, and light energy.

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  1. How to Use This Presentation • To View the presentation as a slideshow with effects select “View” on the menu bar and click on “Slide Show.” • To advance through the presentation, click the right-arrow key or the space bar. • From the resources slide, click on any resource to see a presentation for that resource. • From the Chapter menu screen click on any lesson to go directly to that lesson’s presentation. • You may exit the slide show at any time by pressing the Esc key.

  2. Resources Bellringers Chapter Presentation Transparencies Standardized Test Prep Image and Math Focus Bank CNN Videos Visual Concepts

  3. Energy and Energy Resources Chapter 9 Table of Contents Section 1 What Is Energy? Section 2 Energy Conversions Section 3 Conservation of Energy Section 4 Energy Resources

  4. Chapter 9 Section1 What Is Energy? Bellringer Copy and finish the following sentence: “Energy is the ability to ____.” What is the distinction between energy and power?

  5. Chapter 9 Section1 What Is Energy? Objectives • Explain the relationship between energy and work. • Compare kinetic energy and potential energy. • Describe the different forms of energy.

  6. Chapter 9 Section1 What Is Energy? Energy and Work: Working Together • Energy is the ability to do work. From bellringer • Work is done when a force causes an object to move in the direction of the force. Work is a transfer of energy. • Energy and work are expressed in units of joules (J).

  7. Chapter 9 Section1 What Is Energy?

  8. m v 2 k i n e t i c e n e r g y = 2 Chapter 9 Section1 What Is Energy? Kinetic Energy • Kinetic energy is the energy of motion. All moving objects have kinetic energy. • Kinetic Energy Depends on Mass and Speed If you know an object’s mass (m) and its speed (v), you can calculate the object’s kinetic energy with the following equation: • KE = V x V x M x .5

  9. Chapter 9 Section1 What Is Energy? Kinetic Energy Click below to watch the Visual Concept. You may stop the video at any time by pressing the Esc key. Visual Concept

  10. Chapter 9 Section1 What Is Energy?

  11. Chapter 9 Section1 What Is Energy? Potential Energy • Potential energy is the energy an object has because of its position. • Gravitational Potential Energy The amount of gravitational potential energy that an object has depends on its weight and its height.

  12. Chapter 9 Section1 What Is Energy? Potential Energy, continued • Calculating Gravitational Potential Energy The equation to find gravitational potential energy is: • gravitational potential energy  weight  height • Gravitational potential energy is equal to the amount of work done on an object to lift it a certain height.

  13. Chapter 9 Section1 What Is Energy?

  14. Chapter 9 Section1 What Is Energy? Potential Energy, continued • Height Above What? When you find out an object’s gravitational potential energy, the “ground” that you measure the object’s height from depends on where it is. • The height you use in calculating gravitational potential energy is a measure of how far an object has to fall.

  15. Chapter 9 Section1 What Is Energy? Mechanical Energy • Mechanical energy is the total energy of motion and position of an object. Both kinetic energy and potential energy are kinds of mechanical energy. • The equation to find mechanical energy is: • mechanical energy  potential energy  kinetic energy

  16. Chapter 9 Section1 What Is Energy? Mechanical Energy, continued • The mechanical energy of an object remains the same unless it transfers some energy to another object. • But even if the mechanical energy of an object stays the same, the potential energy or kinetic energy can increase or decrease.

  17. Chapter 9 Section1 What Is Energy? Other Forms of Energy • Thermal Energy is all of the kinetic energy due to random motion of the particles that make up an object. • All matter is made up of particles that are always in random motion. So, all matter has thermal energy. • Thermal energy increases as temperature increases and increases as the number of particles increases.

  18. Chapter 9 Section1 What Is Energy?

  19. Chapter 9 Section1 What Is Energy? Other Forms of Energy, continued • Chemical Energy is the energy of a chemical compound that changes as its atoms are rearranged. • Chemical energy is a form of potential energy because it depends on the position and arrangement of the atoms in a compound. • The energy in food is chemical energy.

  20. Chapter 9 Section1 What Is Energy? Other Forms of Energy, continued • Electrical Energy is the energy of moving electrons. Electrical energy can be thought of as potential energy that is used when you plug in an electrical appliance and use it. • Sound Energy is caused by an object’s vibrations. The object’s vibrations transmit some kinetic energy to the air particles, which also vibrate. These vibrations transmit sound energy.

  21. Chapter 9 Section1 What Is Energy? Other Forms of Energy, continued • Light Energy is produced by the vibrations of electrically charged particles. • Nuclear Energy is energy that comes from changes in the nucleus of an atom. Nuclear energy can beproduced when nuclei are joined in a fusion reaction or when a nucleus is split apart in a fission reaction.

  22. Chapter 9 Section2 Energy Conversions Bellringer What do the following a plant, a Bunsen burner, and a pendulum have in common? What are three other objects that have same common link? Write your answers in yourscience journal.

  23. Chapter 9 Section2 Energy Conversions Objectives • Describe an energy conversion. • Give examples of energy conversions for the different forms of energy. • Explain how energy conversions make energy useful. • Explain the role of machines in energy conversions.

  24. Chapter 9 Section2 Energy Conversions Kinetic Energy and Potential Energy • An energy conversion is a change from one form of energy to another. Any form of energy can change into any other form of energy. • As the skateboarder on the next slide travels up and down the half-pipe, his energy changes back and forth between kinetic energy and potential energy.

  25. Chapter 9 Section2 Energy Conversions

  26. Chapter 9 Section2 Energy Conversions Kinetic Energy and Potential Energy, continued • Elastic Potential Energy Stretching a rubber band stores elastic potential energy in the rubber band. • When you let the rubber band go, it goes back to its original shape. It releases its stored-up potential energy as it does so.

  27. Chapter 9 Section2 Energy Conversions Conversions Involving Chemical Energy • Chemical energy is stored in the food you eat. Your body uses this chemical energy to function. • Energy Conversion in PlantsThe chemical energy in the food you eat comes from the sun’s energy.Plants use photosynthesis to convert light energy into chemical energy, as shown on the next slide.

  28. Chapter 9 Section2 Energy Conversions

  29. Chapter 9 Section2 Energy Conversions Conversions Involving Chemical Energy, continued • The Process Continues Plants change light energy into chemical energy. The chemical energy in the food you eat is changed into another kind of chemical energy that your body can use. • Your body then uses that energy to give you kinetic energy that you use in everything you do.

  30. Chapter 9 Section2 Energy Conversions Why Energy Conversions Are Important • Energy conversions are needed for everything we do. Heating our homes, getting energy from a meal, and many other things use energy conversions. • Machines, such as a hair dryer, help harness energy and make that energy work for you.

  31. Chapter 9 Section2 Energy Conversions Why Energy Conversions Are Important, continued • Conversions Involving Electrical Energy Some common energy conversions that involve electrical energy are shown in the table below.

  32. Chapter 9 Section2 Energy Conversions Energy and Machines • A machine can make work easier by changing the size or direction (or both) of the force needed to do the work. Some machines allow you to use less force over a greater distance to do the same amount of work. • Machines as Energy ConvertersSome machines help you use energy by converting it into the form of energy that you need.

  33. Chapter 9 Section2 Energy Conversions

  34. Chapter 9 Section3 Conservation of Energy Bellringer Answer the following questions: Where does the energy that makes a roller coaster car move come from? Where does the energy go? What does “All of the energy put into a process still exists somewhere when the process has ended” mean? Write your answers in yourscience journal.

  35. Chapter 9 Section3 Conservation of Energy Objectives • Explain how energy is conserved within a closed system. • Explain the law of conservation of energy. • Give examples of how thermal energy is always a result of energy conversion. • Explain why perpetual motion is impossible.

  36. Chapter 9 Section3 Conservation of Energy Where Does the Energy Go? • Friction is a force that oppose motion between two surfaces that are touching. • For a roller coaster car to move, energy must be used to overcome the friction between the car’s wheels and the track. • As a result, not all of the car’s potential energy changes into kinetic energy and not all of the car’s kinetic energy changes back into potential energy.

  37. Chapter 9 Section3 Conservation of Energy

  38. Chapter 9 Section3 Conservation of Energy Energy Is Conserved Within a Closed System • A closed system is a group of objects that transfer energy only to each other. • TheLaw of Conservation of Energystates that energy cannot be created or destroyed. • Energy can be converted from one form to another. But all of the different forms of energy in a system always add up to the same total amount of energy.

  39. Chapter 9 Section3 Conservation of Energy Energy Is Conserved Within a Closed System, continued • The image below shows energy conservation in a light bulb.

  40. Chapter 9 Section3 Conservation of Energy No Conversion Without Thermal Energy • Any time one form of energy is converted into another form, some of the original energy always gets converted into thermal energy. • The thermal energy due to friction that results from energy conversions is not usually useful energy.

  41. Chapter 9 Section3 Conservation of Energy No Conversion Without Thermal Energy, continued • Perpetual Motion? No Way!A perpetual motion machine is a machine that would run forever without any additional energy. But this is not possible because some energy is always wasted as thermal energy. • But perpetual motion machines are impossible because some waste thermal energy always results from energy conversions.

  42. Chapter 9 Section3 Conservation of Energy No Conversion Without Thermal Energy, continued • Making Conversions EfficientSome systems transform energy with less loss of heat than others do. Such systems are more efficient than others are. • Improving the efficiency of machines is important because greater efficiency results in less waste. If less energy is wasted, less energy is needed to operate a machine.

  43. Chapter 9 Section4 Energy Resources Bellringer Predict whether the following sources of energy are renewable or nonrenewable. sunlight coal wind petroleum nuclear geothermal Write and explain your predictions in yourscience journal.

  44. Chapter 9 Section4 Energy Resources Objectives • Name several energy resources. • Explain how the sun is the source of most energy on Earth. • Evaluate the advantages and disadvantages of using various energy resources.

  45. Chapter 9 Section4 Energy Resources Nonrenewable Resources • Nonrenewable resources cannot be replaced or are replaced much more slowly than they are used. • Fossil fuels are nonrenewable energy resources that formed from the remains of organisms that lived long ago. Oil, natural gas, and coal are the most common fossil fuels.

  46. Chapter 9 Section4 Energy Resources

  47. Chapter 9 Section4 Energy Resources Nonrenewable Resources, continued • Uses of Fossil Fuels All fossil fuels contain stored energy from the sun, which can be converted into other kinds of energy. • Burning coal is a common way to generate electrical energy. Petroleum is used to make gasoline, wax, and plastics. Natural gas is often used in home heating.

  48. Chapter 9 Section4 Energy Resources Nonrenewable Resources, continued • Electrical Energy from Fossil FuelsElectric generators convert the chemical energy in fossil fuels into electrical energy by the process shown below.

  49. Chapter 9 Section4 Energy Resources Nonrenewable Resources, continued • Nuclear Energy Another way to generate electrical energy is to use nuclear energy. • In a process called nuclear fission, the nucleus of a radioactive atom is split into two smaller nuclei, which releases nuclear energy. • Because the supply of radioactive elements is limited, nuclear energy is a nonrenewable resource.

  50. Chapter 9 Section4 Energy Resources Renewable Resources • Renewable resourcesare naturally replaced more quickly than they are used. • Examples of renewable resources: • #1 Solar Energy Sunlight can be changed into electrical energy through solar cells. • Solar cells can be used in devices such as calculators. They can also be placed on the roof of a house to provide electrical energy.

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