A 1.00 kg ball is thrown directly upward with an initial speed of 16.0 m/s.

A graph of the ball's gravitational potential energy vs. height, Ug(h), for an arbitrary initial velocity is given in Part A. The zero point of gravitational potential energy is located at the height at which the ball leaves the thrower's hand.

For this problem, take g=10.0m/s2 as the acceleration due to gravity.

Draw a new gravitational potential energy vs. height graph to represent the gravitational potential energy if the ball had a mass of 2.00 kg. The graph for a 1.00-kg ball with an arbitrary initial velocity is provided again as a reference.

A baseball is thrown directly upward at time and is caught again at time . Assume that air resistance is so small that it can be ignored and that the zeropoint of gravitational potential energy is located at the positionat which the ball leaves the thrower's hand.

a. Sketch a graph of the kinetic energy of the baseball.

b. Based on the graph of kinetic energy, sketch a graph of thebaseball's gravitational potential energy.

c. Based on the kinetic and potential energy graphs, sketch a graphof the baseball's total energy.

A baseball is thrown directly upward at time and is caught again at time . Assume that air resistance is so small that it can be ignored and that the zero point of gravitational potential energy is located at the position at which the ball leaves the thrower's hand. Sketch a graph of the kinetic energy of the ball. Plot points at half second intervals.

A baseball is thrown directly upward at time t=0 and is caught again at time t=5 sec. Assume that the air friction is so small that it can be ignored and that the zero points of gravitational potential energy are located at the position at which the ball leaves the thrower's hand.

Sketch a graph of the kinetic energy of the ball.