An irresponsible adult hurls a boomerang into the air with a center of mass velocity of 32.0 m/s at an angle of 43 degrees with respect to the horizontal (Figure 10.22).  It has a mass of 1.2 kg and is rotating at 10.0 rev/s.  The moment of inertia of the boomerang is given as I = 1/12 ML² where L = 0.7 m.  What is the total kinetic energy of the boomerang when it leaves the hand?

711.1 J

1422.2 J

614.4 J

96.7 J

Transcribed Image Text:

The image portrays a person throwing a boomerang. The details of the diagram are as follows: - The person is shown extending their arm forward, aiming to throw a boomerang. - There is a dashed line illustrating the path of the boomerang from the person's hand. - The boomerang is depicted in mid-air at a point above the person. - An angle of 40 degrees is marked between the dashed line representing the throw trajectory and a horizontal baseline running from the person’s shoulder. - This angle indicates the optimal throwing angle for the boomerang to achieve a successful flight that returns to the thrower. This diagram emphasizes the importance of the throwing angle in achieving a successful boomerang throw.

Transcribed Image Text:

**Figure 13.20: A wind turbine in action.** This figure illustrates a wind turbine with three blades. The arrows around the turbine indicate the rotation direction of the blades, which is clockwise when viewed from the front. This rotation is a result of the wind turning the blades, which is the fundamental operation of a wind turbine. The kinetic energy of the wind is converted into mechanical energy through this rotational motion, which can subsequently be transformed into electrical energy for various uses. Wind turbines are a crucial component of sustainable energy solutions, harnessing wind power to generate electricity without emitting greenhouse gases.