A stone is held at a height h above the ground. A second stone with two...

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 stone is dropped at t = 0. A second stone, with 3 times the mass...

A stone is dropped at t = 0. A second stone, with 3 times the mass of the first, is dropped from the same point at t = 100 ms. (a) How far below the release point is the center of mass of the two stones at t = 390 ms? (Neither stone has yet reached the ground.) (b) How fast is the center of mass of the two-stone system moving at that time?

A stone is dropped at t = 0. A second stone, with 5 times the mass...

A stone is dropped at t = 0. A second stone, with 5 times the mass of the first, is dropped from the same point at t = 74 ms. (a) How far below the release point is the center of mass of the two stones at t = 270 ms? (Neither stone has yet reached the ground.) (b) How fast is the center of mass of the two-stone system moving at that time?

qt9.2 A stone is dropped at t = 0. A second stone, with 5 times the...

qt9.2 A stone is dropped at t = 0. A second stone, with 5 times the mass of the first, is dropped from the same point at t = 170 ms. (a) How far below the release point is the center of mass of the two stones at t = 430 ms? (Neither stone has yet reached the ground.) (b) How fast is the center of mass of the two-stone system moving at that time?

stone is thrown upward with velocity v from a height h. Its elevation d above the...

stone is thrown upward with velocity v from a height h. Its elevation d above the ground at time t is given by d = at2 + vt + h The elevation is measured at three different times as shown. Time (s) 1.0 2.0 6.0 Elevation (ft) 144 192 64

An electron is held 18.0 m above the ground. How far apart would two different electrons...

An electron is held 18.0 m above the ground. How far apart would two different electrons need to be held in order to have the same potential energy as the first electron? What is the potential 5.3 mm away from a 1.6 μC point charge? a. What distance from a 15 nC charge would have the same potential?

two balls are thrown upward and reach height h. The first ball reaches the ground level...

two balls are thrown upward and reach height h. The first ball reaches the ground level at a speed of 5 m/s and the second ball at 5.5 m/s. The speed of the first ball at height h is 2 m/s. Find the speed of the second ball at height h by using the principle of conservation of energy

A stone is projected at a cliff of a height h with an initial speed of...

A stone is projected at a cliff of a height h with an initial speed of 42.0 m/s directed 60.0 degrees above the horizontal. The stone strikes the cliff 5.50 s after launching. 1. Find the horizontal distance traveled by the stone. 2. what is the height of the cliff. 3. what is the speed of the stone just before impact. 4. what is the maximum height reached above the ground.

A rock is dropped, from rest, from a height of 8.9 m above the ground at...

A rock is dropped, from rest, from a height of 8.9 m above the ground at t = 0 s. At the same time that the rock is dropped a stone is thrown upward from a height of 1.1 m above the ground at a speed of 7.1 m/s. The stone travels straight upward toward the rock. There is no air resistance. a. Determine the height above the ground where the rock hits with the stone. Blank 1. Calculate the...

The drawing shows two frictionless inclines that begin at ground level (h = 0 m) and...

The drawing shows two frictionless inclines that begin at ground level (h = 0 m) and slope upward at the same angle θ. One track is longer than the other, however. Identical blocks are projected up each track with the same initial speed v0. On the longer track the block slides upward until it reaches a maximum height H above the ground. On the shorter track the block slides upward, flies off the end of the track at a height...