Kinetic Energy & Work Pg. 171 - 176. Kinetic Energy  Recall:  A moving object has the ability to do work because it can apply a force to another object.

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Presentation transcript:

Kinetic Energy & Work Pg

Kinetic Energy  Recall:  A moving object has the ability to do work because it can apply a force to another object and displace it  The energy possessed by moving objects is called kinetic energy (E k )  For example, a moving hammer has kinetic energy because it has the ability to apply a force on a nail and push the nail into a piece of wood  (the faster the hammer moves or the greater its mass, the greater its kinetic energy, and the greater the displacement of the nail)

Kinetic Energy (E k )  Energy possessed by a moving object note

Practice  1. By what factor does a car’s kinetic energy increase when the car’s speed:  A) doubles  B) triples  C) increases by 26%

Kinetic Energy & Work  Now, imagine a cart is moving with an initial speed of v i when it experiences a force that causes it’s speed to increase to v f over a displacement of ∆d

Kinetic Energy & Work  In this case, the work done on the cart is equal to the change in the kinetic energy of the cart. This is known as the work-energy theorem  You can use this theorem to solve several types of physics problems…..however, the theorem is only true if no energy losses occur  In many real-world situations, energy will seem to disappear in the form of light, sound, heat or changes in the shape of an object  For example, in a car collision, energy goes into the sounds of the crash and the bending of the materials in the car (in this case, the work done on the car does NOT equal the change in the kinetic energy of the car)

Work-Energy Theorem  Only true if no energy losses occur note

Practice  2. A whale with a mass of kg is swimming with a speed of 6.1 m/s. A nearby boat startles the whale, and the whale increases its speed to 12.8 m/s. Calculate the work done by the water on the whale.  3. A police car of mass 2.4 x 10 3 kg is travelling on the highway when the officers receive an emergency call. They increase the speed of the car to 33 m/s. The increase in speed results in 3.1 x 10 5 J of work done on the car. Determine the initial speed of the police car in km/h

Practice  4. An archer pulls back her bowstring, loaded with a 22 g arrow, and then releases the string. If the arrow leaves the bowstring at a speed of 220 km/h, calculate the work done on the arrow by the bowstring.  5. Two objects have the same kinetic energy. One has a speed that is 2.5 times the speed of the other. Determine the ratio of their masses. (Hint: assume v i = 2.5v f ) Textbook Q’s: pg. 176 #1, 3, 5, 7, 9 (suggested reading: section 4.2, pg. 171)