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Energy: Forms and Changes

Energy: Forms and Changes. Nature of Energy. Energy is all around you! You can hear energy as sound. You can see energy as light. And you can feel it as wind. Nature of Energy. You use energy when you: hit a softball. lift your book bag. compress a spring. Nature of Energy.

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Energy: Forms and Changes

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  1. Energy: Forms and Changes

  2. Nature of Energy • Energy is all around you! • You can hear energy as sound. • You can see energy as light. • And you can feel it as wind.

  3. Nature of Energy • You use energy when you: • hit a softball. • lift your book bag. • compress a spring.

  4. Nature of Energy Living organisms need energy for growth and movement.

  5. Nature of Energy • Energy is involved when: • a bird flies. • a bomb explodes. • rain falls from the sky. • electricity flows in a wire.

  6. Nature of Energy • What is energy that it can be involved in so many different activities? • Energy can be defined as the ability to do work. • If an object or organism does work (exerts a force over a distance to move an object) the object or organism uses energy.

  7. Nature of Energy • Because of the direct connection between energy and work, energy is measured in the same unit as work: joules (J). • In addition to using energy to do work, objects gain energy because work is being done on them.

  8. Forms of Energy • The seven main forms of energy are: • Thermal • Chemical • Radiant • Nuclear • Mechanical • Sound • Electric

  9. Thermal Energy • The internal motion of the atoms is called thermal energy, because moving particles produce heat. • Thermal energy can be produced by friction. • Thermal energy causes changes in temperature and phase of any form of matter.

  10. Chemical Energy • Chemical Energy is required to bond atoms together. • And when bonds are broken, energy is released.

  11. Chemical Energy • Fuel and food are forms of stored chemical energy.

  12. Electromagnetic Energy • Light is a form of electromagnetic energy. • Each color of light (Roy G Bv) represents a different amount of electromagnetic energy. • Electromagnetic Energy is also carried by X-rays, radio waves, and laser light.

  13. Nuclear Energy • The nucleus of an atom is the source of nuclear energy.

  14. Nuclear Energy • When the nucleus splits (fission), nuclear energy is released in the form of heat energy and light energy. • Nuclear energy is also released when nuclei collide at high speeds and join (fuse).

  15. Nuclear Energy The sun’s energy is produced from a nuclear fusion reaction in which hydrogen nuclei fuse to form helium nuclei.

  16. Nuclear Energy • Nuclear energy is the most concentrated form of energy.

  17. Mechanical Energy • When work is done to an object, it acquires energy. The energy it acquires is known as mechanical energy.

  18. Energy Conversion • Energy can be changed from one form to another. Changes in the form of energy are called energy conversions.

  19. Energy conversions • All forms of energy can be converted into other forms. • The sun’s energy through solar cells can be converted directly into electricity. • Green plants convert the sun’s energy (electromagnetic) into starches and sugars (chemical energy).

  20. Other energy conversions • In an electric motor, electromagnetic energy is converted to mechanical energy. • In a battery, chemical energy is converted into electromagnetic energy. • The mechanical energy of a waterfall is converted to electrical energy in a generator.

  21. Energy Conversions • In an automobile engine, fuel is burned to convert chemical energy into heat energy. The heat energy is then changed into mechanical energy.

  22. Chemical  Heat Mechanical

  23. States of Energy • The most common energy conversion is the conversion between potential and kinetic energy. • All forms of energy can be in either of two states: • Potential • Kinetic

  24. States of Energy: Kinetic and Potential Energy • Kinetic Energy is the energy of motion. • Potential Energy is stored energy.

  25. Potential Energy • Potential Energy is stored energy. • Stored chemically in fuel, the nucleus of atom, and in foods. • Or stored because of the work done on it: • Stretching a rubber band. • Winding a watch. • Pulling back on a bow’s arrow. • Lifting a brick high in the air.

  26. Gravitational Potential Energy • Potential energy that is dependent on height is called gravitational potential energy.

  27. Potential Energy • Energy that is stored due to being stretched or compressed is called elastic potential energy.

  28. Gravitational Potential Energy • A waterfall, a suspension bridge, and a falling snowflake all have gravitational potential energy.

  29. Gravitational Potential Energy • If you stand on a 3-meter diving board, you have 3 times the G.P.E, than you had on a 1-meter diving board.

  30. Gravitational Potential Energy • “The bigger they are the harder they fall” is not just a saying. It’s true. Objects with more mass have greater G.P.E. • The formula to find G.P.E. is G.P.E. = Weight X Height.

  31. Let’s Practice A flower pot with a mass of 15 kg is sitting on a window sill 15 meters above the ground. How much potential energy does the flower pot contain? • PE = (mass)(gravity)(height) • = (15 kg)(9.8 m/s2)(15 m) • = 2205 kg • m2/s2 or J

  32. Let’s Practice A rock has a mass of 8.40 x 104 kg. The center of mass is 29.0 m above the ground. How much energy does it have? PE = mgh Identify the variables m= 8.40 x 104 kg g= 9.81 m/s2 h= 29.0 m PE = (8.4X104)(9.81)(29) = 2.39 x 107 J http://gaaf.com/pictures/200406_utah/image009.htm

  33. Kinetic Energy • The energy of motion is called kinetic energy. • The faster an object moves, the more kinetic energy it has. • The greater the mass of a moving object, the more kinetic energy it has. • Kinetic energy depends on both mass and velocity.

  34. Kinetic Energy K.E. = mass x velocity 2 What has a greater affect of kinetic energy, mass or velocity? Why? 2

  35. Let’s Practice What is the kinetic energy of this car when it is traveling 38.0 m/s? What other information do you need? KE = ½ m v2 = ½ (1550)(38.0)2 = 1119100 J = 1.11 x 106 J Car’s mass = 1550kg

  36. Let’s Practice A bicycle with a mass of 14 kg traveling at a velocity of 3.0 m/s east has how much kinetic energy? KE = 0.5mv2 m = 14 kg v = 3.0 m/s E = 0.5(14 kg)(3.0 m/s)2 = 0.5(14 kg)(9.0 m2/s2) = 63 kg• m2/s2 = 63 J

  37. Kinetic-Potential Energy Conversion Roller coasters work because of the energy that is built into the system. Initially, the cars are pulled mechanically up the tallest hill, giving them a great deal of potential energy. From that point, the conversion between potential and kinetic energy powers the cars throughout the entire ride.

  38. Recap • Energy in a system may take on various forms (e.g. kinetic, potential, thermal, radiant). • The law of conservation of energy states that energy may neither be created nor destroyed. • Therefore the sum of all the energies in the system is a constant.

  39. Kinetic vs. Potential Energy At the point of maximum potential energy, the car has minimum kinetic energy.

  40. Kinetic-Potential Energy Conversions • As a basketball player throws the ball into the air, various energy conversions take place.

  41. Ball speeds up Ball slows down

  42. The Law of Conservation of Energy • Energy can be neither created nor destroyed by ordinary means. • It can only be converted from one form to another. • If energy seems to disappear, then scientists look for it – leading to many important discoveries.

  43. Law of Conservation of Energy • In 1905, Albert Einstein said that mass and energy can be converted into each other. • He showed that if matter is destroyed, energy is created, and if energy is destroyed mass is created. 2 • E = MC

  44. The most commonly used example of conservation of energy is the pendulum:

  45. Mechanical Energy The sum of PE and KE is the total mechanical energy: ME = PE + KE

  46. NOTE: This is with the absence of outside forces such as friction • Using our common sense we know that it's impossible for the pendulum to swing higher than the height h without giving it a push yourself. • If there was no friction, the pendulum would swing back and forth forever because of the law of conservation of energy.

  47. Let’s practice • A 2.0 kg toy dump truck moving with a speed of 3.0 m/s starts up a ramp. How high does the car roll before it stops? • Pe(top) = Ke(bottom) • mgh = 1/2mv2 or gh = 1/2v2 • 9.8 * h = ½(3)2 • h = 0.459 m

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