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D. Roberts PHYS 121 University of Maryland Physic² 121: Phundament°ls of Phy²ics I October 25, 2006.

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Presentation on theme: "D. Roberts PHYS 121 University of Maryland Physic² 121: Phundament°ls of Phy²ics I October 25, 2006."— Presentation transcript:

1 D. Roberts PHYS 121 University of Maryland Physic² 121: Phundament°ls of Phy²ics I October 25, 2006

2 D. Roberts PHYS 121 University of Maryland Work Summary Work is a scalar (not a vector); can be positive or negative We can calculate work done by each force in an object free-body diagram The total work done is the sum of the work done by each force separately

3 D. Roberts PHYS 121 University of Maryland More thoughts on Work Look at Work definition: If Force is along the direction of displacement, Work is positive –What happens to speed? If Force is opposite to direction of displacement, Work is negative –What happens to speed? If Force is perpendicular to displacement, Work is zero –What happens to speed? Conclusion: –Positive total work will make something speed up –Negative total work will make something slow down –Zero total work won’t change speed Doesn’t mean direction can’t change!

4 D. Roberts PHYS 121 University of Maryland Work-Kinetic Energy Theorem When work is done by a net force on an object and the only change in the object is its speed, the work done is equal to the change in the object’s kinetic energy –Speed will increase if work is positive –Speed will decrease if work is negative (The “only change speed” condition is there because this isn’t true of the work causes the object to deform or heat up)

5 D. Roberts PHYS 121 University of Maryland Kinetic Energy Energy associated with the motion of an object Scalar quantity with the same units as work Work is related to kinetic energy

6 D. Roberts PHYS 121 University of Maryland Potential Energy Potential energy is associated with the position of the object within some system –Potential energy is a property of the system, not the object –A system is a collection of objects interacting via forces or processes that are internal to the system

7 D. Roberts PHYS 121 University of Maryland Gravitational Potential Energy Gravitational Potential Energy is the energy associated with the relative position of an object in space near the Earth’s surface –Objects interact with the earth through the gravitational force –Actually the potential energy is for the earth-object system

8 D. Roberts PHYS 121 University of Maryland Reference Levels for Gravitational Potential Energy A location where the gravitational potential energy is zero must be chosen for each problem –The choice is arbitrary since the change in the potential energy is the important quantity –Choose a convenient location for the zero reference height often the Earth’s surface may be some other point suggested by the problem –Once the position is chosen, it must remain fixed for the entire problem

9 D. Roberts PHYS 121 University of Maryland Conservation of Mechanical Energy Conservation in general –To say a physical quantity is conserved is to say that the numerical value of the quantity remains constant throughout any physical process In Conservation of Energy, the total mechanical energy remains constant –In any isolated system of objects interacting only through conservative forces, the total mechanical energy of the system remains constant.

10 D. Roberts PHYS 121 University of Maryland Conservation of Energy, cont. Total mechanical energy is the sum of the kinetic and potential energies in the system –Other types of potential energy functions can be added to modify this equation

11 D. Roberts PHYS 121 University of Maryland Conservation of E with Gravity If gravity is the only force acting: Initial KE Initial PE Final PE Final KE

12 ? Two marbles, one twice as heavy as the other, are dropped to the ground from the roof of a building. Just before hitting the ground, the heavier marble has: 12345 as much kinetic energy as the lighter one twice as much kinetic energy as the lighter one half as much kinetic energy as the lighter one four times as much kinetic energy as the lighter one impossible to determine 0 of 5

13 ? A cart on an air track is moving at 0.5 m/s when the air is suddenly turned off. The cart comes to rest after traveling 1 m. The experiment is repeated, but now the cart is moving at 1 m/s when the air is turned off. How far does the cart travel before coming to rest? 12345 1.1m 2.2m 3.3m 4.4m 5.5m 6.Impossible to tell 0 of 5

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