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Understanding the Relationship between Work and Energy

Explore the concepts of work and energy and their relationship. Learn about kinetic and potential energy and how they are determined. Discover the law of conservation of energy and the conversion of energy from one form to another.

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Understanding the Relationship between Work and Energy

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  1. S-41 How is work and energy related? • Define the following terms • A. Work • B. Kinetic Energy • C. Potential Energy

  2. SPS7 Students will relate transformations and flow of energy within a system Identify energy transformations within a system Chapter 15 & 16 Energy

  3. How are energy and work related? What factors does the kinetic energy of an object depend on? How is gravitational potential energy determined? 15.1 Energy and Its Forms

  4. 15.1 Energy and Its Forms How are energy and work related? • Energy – the ability to do work • Measured in joules (J) • Work – a transfer of energy

  5. 15.1 Energy and Its Forms What factors does the kinetic energy of an object depend on? KE = ½mv2 • Kinetic Energy – energy due to motion • Depends on it’s mass and speed • Equation • KE = kinetic energy in Joules (J) • m = mass in kilograms (kg) • v = speed in meters/second (m/s) • Increases rapidly with speed

  6. 15.1 Energy and Its Forms What factors does the kinetic energy of an object depend on? KE = ½(0.10)(8.0)2 KE = ½mv2 KE = 3.2J m = 0.10 kg v = 8.0 m/s • Practice Problem • A 0.10 kg bird is flying at a constant speed of 8.0 m/s. What is the birds kinetic energy? • Variables? • Fill in the Equation? • Answer?

  7. 15.1 Energy and Its Forms How is gravitational potential energy determined? • Potential Energy – stored due to position or shape • Stretched rubber band • Book on a shelf • Springs

  8. 15.1 Energy and Its Forms How is gravitational potential energy determined? PE = mgh 420 ft • Gravitational Potential Energy – due to height • Depends on it’s mass, height, and gravity • Equation • PE = potential energy in Joules (J) • m = mass in kilograms (kg) • g = gravity (9.80 m/s2) • Height is measured from any point – so this value is relative

  9. 15.1 Energy and Its Forms How is gravitational potential energy determined? PE = (50.0)(9.80)(10.0) PE = 4900J PE = mgh h = 10.0 kg m = 50.0 kg • Practice Problem • A diver at the top of a 10.0 meter platform has a mass of 50.0 kg. What is her potential energy? • Variables? • Fill in the Equation? • Answer?

  10. S-42 What factors does the kinetic energy of an object depend on? • A 2000 kg cruise missile is flying at 245 m/s. How many joules of kinetic energy does it have?

  11. Can energy be converted from one form to another? What is the law of conservation of energy? 15.2 Energy Conversion and Conservation

  12. 15.2 Energy Conservation Can energy be converted from one form to another? Energy can be converted from one form to another.

  13. 15.2 Energy Conservation What is the law of conservation of energy? • Law of Conservation of Energy – energy cannot be created or destroyed • We may lose usable energy due to friction • Or because of heat • Other energy loses?

  14. 15.2 Energy Conservation What energy conversion takes place as an object falls toward Earth? PE = KE • When an object falls • It starts with what kind of energy? • Potential • Ends with what kind of energy? • Kinetic • Because of conservation

  15. 15.2 Energy Conservation What energy conversion takes place as an object falls toward Earth? PE = KE PE = ½ (1.50)(26.0)2 PE = ½ mv2 PE = 507J m = 1.50 kg v = 26.0 m/s Practice Problem At a construction site, a 1.50 kg brick is dropped from rest and hits the ground at a speed of 26.0 m/s. What was the gravitational potential energy of the brick before it was dropped? Equation? Variables? Fill in Equation?

  16. S-43 How is gravitational potential energy determined? A 65 kg man bungee jumps from a platform that is 120 m in the air. A. How much potential energy does he have? B. How much kinetic energy will he have at the bottom?

  17. S-44 How is gravitational potential energy determined? Rocket man has a mass of 75 kg and is flying at 45 m/s and a height of 25 m above the ground. A. What is his kinetic energy? B. What is his potential energy? C. What is his total energy?

  18. SPS7 Students will relate transformations and flows of energy within a system Investigate molecular motion as it relates to thermal energy changes in terms of conduction, convection, and radiation. Determine the heat capacity of a substance using mass, specific heat, and temperature. Explain the flow of energy in phase changes through the use of a phase diagram. 16 Thermal Energy and Heat

  19. In what direction does heat flow spontaneously? What is the temperature of an object related to? How is change in temperature related to specific heat? 16.1 Thermal Energy and Matter

  20. 16.1 Thermal Energy & Matter In what direction does heat flow spontaneously? Heat – transfer of thermal energy from one object to another because of temperature differences Heat flows spontaneously from hotter objects to colder objects

  21. 16.1 Thermal Energy & Matter What is the temperature of an object related to? Kinetic Energy Applet • Temperature – a measurement of how hot or cold something is compared to a reference point • Directly related to the average kinetic energy of the particles in an object • When something heats up, the particles move faster • When it cools off, the particles move slower • Energy is transferred by collisions • Fast particles tend to slow down, and slow ones tend to speed up

  22. 16.1 Thermal Energy & Matter How is change in temperature related to specific heat? • Specific Heat – the amount of energy needed to raise the temperature of one gram of material by one degree Celsius. • The lower the specific heat, the faster the temperature will rise or fall • Common specific heats

  23. 16.1 Thermal Energy & Matter How is change in temperature related to specific heat? Q=mcDT The heat energy absorbed by something equals the mass times the specific heat times the change in temperature Q = heat energy in joules (J) m = mass in grams (g) c = specific heat (J/goC) DT = change in temperature in oC

  24. 16.1 Thermal Energy & Matter How is change in temperature related to specific heat? Q=(500)(0.449)(95) Q=21327.5 J Q=mcDT m = 500 g c = 0.449 J/goC DT = 95oC Practice Problem 1 An iron skillet has a mass of 500 grams. The specific heat of iron is 0.449 J/goC. How much heat must be absorbed to raise the skillet’s temperature by 95oC? Variables? Filled in Equation? Answer?

  25. 16.1 Thermal Energy & Matter How is change in temperature related to specific heat? 1200=(75)(4.18)DT DT=3.83oC Q=mcDT Q = 1200J m = 75 g c = 4.18 J/goC Practice Problem 2 In setting up an aquarium, the heater transfers 1,200 J of heat to 75 g of water. The specific heat of water is 4.18 J/goC so how much does the water temperature rise? Variables? Filled in Equation? Answer?

  26. S-45 How is change in temperature related to specific heat? How much energy is absorbed by hot gold (c=.128J/goC) when a 455 g sample is heated from 400oC to 800oC?

  27. Why is conduction slower in gases than in liquids and solids? In what natural cycles do convection currents occur? How does an objects temperature affect radiation? 16.2 Heat and Thermodynamics

  28. 16.2 Heat and Thermodynamics Why is conduction slower in gas than in a liquid and solids? • Three ways to transfer heat energy • Conduction – two objects must be in contact • Because of collisions between the particles • Slower in gases than in liquids and solids because the particles are farther apart • Don’t collide as often

  29. 16.2 Heat and Thermodynamics Why is conduction slower in gas than in a liquid and solids? • Thermal Conductor (conductor) – transfers energy well • Thermal Insulator (insulator) – transfers energy poorly

  30. 16.2 Heat and Thermodynamics In what natural cycles do convection currents occur? • Convection – transfer of energy when fluids move from one place to another • Fluid – anything that flows • Convection current – when fluids circulate in a loop as it heats up and cools down

  31. 16.2 Heat and Thermodynamics In what natural cycles do convection currents occur? • Natural cycles • Ocean currents • Weather systems • Molten rock in the earth

  32. 16.2 Heat and Thermodynamics How does an objects temperature affect radiation? • Radiation – transfer of energy by waves moving through space • As temperature increases the rate of radiation increases

  33. 16.2 Heat and Thermodynamics What do the different sections of a temperature/energy graph mean? Solid Melting or Freezing Gas Liquid Boiling or Condensing • A temperature and energy graph shows the relationship between thermal energy and temperature.

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