As part of an experiment in physics lab, small metal ball of radius r = 2.1...

A solid sphere of radius r and mass m is released from a rest on a...

A solid sphere of radius r and mass m is released from a rest on a track. At a height h above a horizontal surface. The sphere rolls without slipping with its motion continuing around a loop of radius R<<r A) If R=0.3h, what is the speed of the sphere when it reaches the top of the loop? Your response must be expressed in terms of some or all of the quantities given above and physical and numerical constants B)...

A solid 0.5750-kg ball rolls without slipping down a track toward a loop-the-loop of radius R...

A solid 0.5750-kg ball rolls without slipping down a track toward a loop-the-loop of radius R = 0.6550 m. What minimum translational speed vmin must the ball have when it is a height H = 1.026 m above the bottom of the loop, in order to complete the loop without falling off the track?

A solid 0.595-kg ball rolls without slipping down a track toward a loop-the-loop of radius R...

A solid 0.595-kg ball rolls without slipping down a track toward a loop-the-loop of radius R = 0.7350 m. What minimum translational speed vmin must the ball have when it is a height H = 1.091 m above the bottom of the loop, in order to complete the loop without falling off the track?

A solid metal ball starts from rest and rolls without slipping a distance of d =...

A solid metal ball starts from rest and rolls without slipping a distance of d = 4.2 m down a θ = 38° ramp. The ball has uniform density, a mass M = 4.7 kg and a radius R = 0.33 m. What is the magnitude of the frictional force on the sphere?

A solid metal ball starts from rest and rolls without slipping a distance of d =...

A solid metal ball starts from rest and rolls without slipping a distance of d = 4.2 m down a θ = 38° ramp. The ball has uniform density, a mass M = 4.7 kg and a radius R = 0.33 m. What is the magnitude of the frictional force on the sphere?

a ball of mass M and radius R start from rest at a height of 5.0...

a ball of mass M and radius R start from rest at a height of 5.0 m and rolls down a 20 degree slope as he fig below. what is the linear speed of the ball when it leaves the incline? assuming that the ball rolls without slipping B) a disk of M and radius R start from rest at a height of 5.0 m and rolls down a 20 degree slope as he fig below. what is the linear...

A 2.9 kg solid sphere (radius = 0.15 m) is released from rest at the top...

A 2.9 kg solid sphere (radius = 0.15 m) is released from rest at the top of a ramp and allowed to roll without slipping. The ramp is 0.85 m high and 5.2 m long. 1. When the sphere reaches the bottom of the ramp, what are its total kinetic energy, 2. When the sphere reaches the bottom of the ramp, what is its rotational kinetic energy? 3. When the sphere reaches the bottom of the ramp, what is its...

A uniform hollow spherical ball of mass 1.75 kg and radius 40.0 cm is rolling up...

A uniform hollow spherical ball of mass 1.75 kg and radius 40.0 cm is rolling up a ramp that rises at 30.0° above the horizontal. Speed of the ball at the base of the ramp is 8.20 m/s. Moment of inertia of 2 hollow sphere is given by I=(2/3)m r . (a) What is the angular velocity of the ball at the base of the ramp? (b) Determine how far up the ramp does it roll before it starts to...

3) A Solid Ball, of mass M and radius R rolls from rest down a table-top...

3) A Solid Ball, of mass M and radius R rolls from rest down a table-top ramp of height H and then rolls (horizontally) across a table until it gets to the edge and rolls off the edge and drops a distance h to the floor. (a) At what horizontal distance D (from the table edge) does the ball hit the floor? (b) Rank the following objects from least D to greatest D : Solid Ball, Hollow Sphere, Solid Cylinder,...

The radius of the loop-the-loop shown below is R = 8.000 m. A) From what initial...

The radius of the loop-the-loop shown below is R = 8.000 m. A) From what initial height should the block be released from rest in order for the block to just barely make it through the loop-the-loop? B) How fast is the block moving at the top of the loop-the-loop in the case described in part A above? C) How do your results in parts A and B above change if you double the mass of the block? D) Explain...