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Chapter 3-4a Energy

Chapter 3-4a Energy. 3-1. The Meaning of Work 3-2. Power 3-3. Kinetic Energy 3-4. Potential Energy 3-5. Energy Transformations 3-6. Conservation of Energy 3-7. The Nature of Heat. 3-8. Linear Momentum 3-9. Rockets 3-10. Angular Momentum 3.11 Special Relativity 3.12 Rest Energy

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Chapter 3-4a Energy

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  1. Chapter 3-4a Energy 3-1. The Meaning of Work 3-2. Power 3-3. Kinetic Energy 3-4. Potential Energy 3-5. Energy Transformations 3-6. Conservation of Energy 3-7. The Nature of Heat 3-8. Linear Momentum 3-9. Rockets 3-10. Angular Momentum 3.11 Special Relativity 3.12 Rest Energy 3.13 General Relativity

  2. 3-1. Work Work equals force times distance. W = Fd The SI unit of work is the joule. 1 joule (J) = 1 newton-meter (N · m) W=Fd=(100N)(8m)=800N·m=800J

  3. 3-2. Power Power is the rate at which work is being done: P = W/t SI unit of power is the watt. 1 watt (W) = 1 joule/second (J/s) The kilowatt (kW) is a convenient unit of power for many applications.

  4. Horsepower • James Watt • Perfected the steam engine 200 years ago • Had to provide a comparison to the work output of a horse. He found that: • Typical horse could perform 497 W of work for as much as 10 hours a day • Watt increased the standard to 746 W • 1 horsepower (hp) = 746 W = 0.746 kW • 1 kilowatt (kW) = 1.34 hp • Early steam engines ranged from 4-100 hp

  5. 3-3. Kinetic Energy Telekinesis Video 1 Telekinesis Video 2 Energy is that property something has that enables it to do work. The energy of a moving object is called kinetic energy (KE): KE = ½mv2 where m = mass and v = speed. KE increases very rapidly with speed because of the v2 factor.

  6. 3-4. Potential Energy Potential energy (PE) is the energy an object has by virtue of its position. Gravitational Potential Energy: PE = mgh

  7. 3-5. Energy Transformations Energy can be transformed or converted from one form to another.

  8. 3-5. Energy Transformations Types of Energy 1. Kinetic energy 2. Potential energy 3. Chemical energy 4. Heat energy 5. Electric energy 6. Radiant energy

  9. 3-6. Conservation of Energy The law of conservation of energy states that energy cannot be created or destroyed, although it can be changed from one form to another. Matter can be considered as a form of energy; matter can be transformed into energy and energy into matter according to the law of conservation of energy. Eo = moc2 where Eo = rest energy, mo = rest mass, and c = speed of light (3x108m/s or 186,000 miles/sec).

  10. 3-7. Nature of Heat Count Rumford supported the British in the Revolutionary War and supervised the makingof cannons. He observed that during the boring process heat was given off (frictional heat) that could be used to boil water and could be produced over and over again from the same piece of metal. Heat must be energy.

  11. 3-8. Linear Momentum Linear Momentum is a measure of the tendency of a moving object to continue in motion along a straight line: p = mv

  12. 3-8. Linear Momentum The law of conservation of momentum states: In the absence of outside forces, the total momentum of a set of objects remains the same no matter how the objects interact with one another.

  13. 3-8. Linear Momentum Newton’s Cradle-an example of the conservation of linear momentum.

  14. 3-9. Rockets The momentum of the exhaust gases is balanced by the rocket's upward momentum. Multistage rockets are more efficient than single-stage, and so are widely used.

  15. 3-9. Rockets Rockets are a version of Newton’s third law of motion as well as the conservation of linear momentum.

  16. 3-10. Angular Momentum Angular momentum is a measure of the tendency of a rotating object to continue spinning about a fixed axis L=mvr L= angular Momentum m=mass circling v=velocity of rotation r=distance from center The smaller the “r” the faster the “v”. Angular momentum is conserved.

  17. 3-10. Angular Momentum • Definition: • The more angular momentum an object has, the greater its tendency to continue to spin (and be stable) • Toy tops • Footballs • The earth • Bullets • Defining angular momentum is complicated; depends on… • How fast the object is turning • Mass of the object • How the mass is distributed (the further the mass is from the center of the object, the greater the angular momentum)

  18. 3-10. Angular Momentum Gyroscopes The Segway Due to angular momentum, when a force is applied in one direction, the combined forces, including the angular momentum, will be in a perpendicular direction. http://www.youtube.com/watch?v=GeyDf4ooPdo

  19. 3-10. Angular Momentum Naval Gyroscopes used to stabilize ships and guns

  20. Naval Ship Stabilization Naval Gyroscopes used to stabilize ships and guns

  21. 3-11. Special Relativity Albert Einstein (1879-1955) published the special theory of relativity in 1905. Special relativity is based on two postulates: 1. The laws of physics are the same in all frames of reference moving at constant velocity. 2. The speed of light (c ) in free space has the same value for all observers (c = 3 x 108 m/s)

  22. 3-11. Special Relativity mo = mγ heavier to = t / γ slower lo = l / γ shorter Twin Paradox Muon Experiment • •

  23. 3-11. Special Relativity Twin Paradox Muon Experiment http://www.youtube.com/watch?v=qgC-NDpt-mw http://www.youtube.com/watch?v=DWKn_Punrjk http://www.youtube.com/watch?v=gdRmCqylsME

  24. 3.12 Rest Energy

  25. 3.12 Rest Energy • E = mc2 or Energy and Mass are the same! • Example 3.8 p 91 • How much mass is converted to energy in a 100MW nuclear power plant? T=(60)(60)(24)= 86,400 s/day E=Pt=108W(86,400 s/day)=8.64 x 1012J m = E/c2 = 8.64 x 1012J/(3 x 108m/s)2 m = 9.6 x 10-5kg or about 0.000013 oz

  26. 3-13. General Relativity General theory of relativity was developed by Einstein in 1916, which related gravitation to the structure of space and time and showed that even light was subject to gravity.

  27. Chapter 4 Energy 4-2 Energy Consumption 4.3 Global Warming 4.4 Greenhouse Effect 4.5 Liquid Fuels 4.6 Natural Gas 4.7 Coal 4.8 A Nuclear World 4.13 The Future

  28. 4.1 The Energy Problem 1. Oil and natural gas reserves will last about another century.. 2. Although coal reserves will last several hundred more years, mining coal is dangerous, and burning coal creates environmental problems such as acid rain, air pollution, and enhanced global warming. 3. The potential for a large-scale nuclear accident is present. 4. Discharge of radioactive wastes into the environment from badly run nuclear power plants has occurred. 5. An unsolved disposal problem of radioactive nuclear waste exists.

  29. 4.2 Energy Consumption Energy consumption 2003

  30. Fig.4.5

  31. 4.3 Global Warming • Greenhouse Effect

  32. 4.3 Global Warming • Atmospheric CO2 • Controlled by water cycle • Could increase temperature by 10oC

  33. 4.3 Global Warming

  34. 4.3 Global Warming

  35. 4.3 Global Warming

  36. 4.3 Global Warming

  37. 4.3 Global Warming

  38. Use of Various Fuels

  39. 4.5 Liquid Fuels Petroleum, a mixture of various hydrocarbons, is the source of most liquid fuels.

  40. 4.5 Hydroelectric Energy

  41. 4.6 Gas Fuels Natural gas is largely methane, CH4. Coal can be gasified Syngas

  42. 4.6 Natural Gas

  43. 4.7 Solid Fuels Types of solid fuels include coal, wood, and coke

  44. 4.7 Coal

  45. 4.7 Solid Fuels Acid rain from sulfur impurities in coal.

  46. 4.8 A Nuclear World Chernobyl Nuclear Accident

  47. 4.8 A Nuclear World Chernobyl Nuclear Accident http://www.ems.psu.edu/~radovic/Chernobyl.html

  48. 4.8 A Nuclear World

  49. 4-13. The Future

  50. Fig. 3.42

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