Determine the work done by gravity when an arrow of mass 0.04 kg is fired vertically...

An object with a mass of 40.0 kg is fired with an initial speed of 1.28...

An object with a mass of 40.0 kg is fired with an initial speed of 1.28 x 102 m/s at an angle of 30.0° above the horizontal from a 116 m high cliff (take ground level to be y = 0 m). (a) Determine the initial total mechanical energy of the projectile. (b) If when the projectile is at its maximum height of y = 287 m, it is traveling 90.7 m/s, determine the amount of work that has been...

A stone 0.44 kg mass is released from rest from a height of 29.4 m above...

A stone 0.44 kg mass is released from rest from a height of 29.4 m above the ground. Ignoring air resistance and letting the ground be the zero potential energy level, Determine the final kinetic energy of the stone using energy conservation principle only, not as a free fall. Determine the work done on the stone by gravity.

A 4.0 kg mass starting at rest is dropped from a height of 120 m above...

A 4.0 kg mass starting at rest is dropped from a height of 120 m above the surface of the Earth. As it falls it experiences an air resistance of 13 N. Just before it strikes the ground, determine the change in potential energy ΔU, the work done by the air W, the final kinetic energy Kf, and its final speed vf

A 4.0 kg mass starting at rest is dropped from a height of 120 m above...

A 4.0 kg mass starting at rest is dropped from a height of 120 m above the surface of the Earth.  As it falls it experiences an air resistance of 13 N.  Just before it strikes the ground, determine the change in potential energy ΔU, the work done by the air W, the final kinetic energy Kf, and its final speed vf.

A 265-kg load is lifted 23.0 m vertically with an acceleration by a single cable. Determine...

A 265-kg load is lifted 23.0 m vertically with an acceleration by a single cable. Determine (a) the tension in the cable; (b) the net work done on the load; (c) the work done by the cable on the load; (d) the work done by gravity on the load; (e) the final speed of the load assuming it started from rest.

If an object of mass 2 kg is thrown up from the ground reaches a height...

If an object of mass 2 kg is thrown up from the ground reaches a height of 5 m and falls back to the Earth (neglect the air resistance). The total work in J done by gravity both in upward and downward motion is:

A 44.0-kg projectile is fired at an angle of 30.0° above the horizontal with an initial...

A 44.0-kg projectile is fired at an angle of 30.0° above the horizontal with an initial speed of 144 m/s from the top of a cliff 120 m above level ground, where the ground is taken to be y = 0. (a) What is the initial total mechanical energy of the projectile? (Give your answer to at least three significant figures.) (b) Suppose the projectile is traveling 102.1 m/s at its maximum height of y = 336 m. How much...

A 285- kg load is lifted 24.0 m m vertically with an acceleration a =0.130 g...

A 285- kg load is lifted 24.0 m m vertically with an acceleration a =0.130 g g by a single cable. Part A Determine the tension in the cable. Determine the net work done on the load. Determine the work done by the cable on the load. Determine the work done by gravity on the load. Determine the final speed of the load assuming it started from rest.

A ball of mass 5.93 kg is released from rest at height 7.62 m above the...

A ball of mass 5.93 kg is released from rest at height 7.62 m above the floor. It falls, hits the ground, and rebounds to height 3.2 m above the floor. Assume none of the losses are due to air friction. Find the work done against friction, in J, on the ball during the contact with the ground

A 0.240 g pebble is fired at a speed of 14.6 m/s from the top of...

A 0.240 g pebble is fired at a speed of 14.6 m/s from the top of a 20.0 m tall building. Ignoring air resistance, find the kinetic energy with which the pebble strikes the ground when the pebble is fired vertically straight up. A ball which is thrown straight up takes 3.50 s to reach the maximum height. Determine the gravitational potential energy of the ball (m = 0.145 kg) when it reaches the maximum height.