A thin spherical shell of radius 0.37 meters rolls down a 6.13 meter high hill without...

A spherical shell of mass M is released from rest and rolls without slipping down a...

A spherical shell of mass M is released from rest and rolls without slipping down a 40.00 sloped hill. Determine the center of mass speed of the object when the ball has rolled 6.00 meters along the hill. Ignore any thickness of the shell. Please show work and possible thoughts

A 1.0 kg spherical mass with a 10-cm radius rolls without slipping 5.0 meters down a...

A 1.0 kg spherical mass with a 10-cm radius rolls without slipping 5.0 meters down a 30degree incline. Isphere=(2/5)MR^2 a. what is the angular velocity of the sphere at the bottom of the ramp? b. through what angle has the sphere rotated? c. what is the angular acceleration of the sphere as it rolls down the incline? d. how much time did it take to roll down the incline?

A basketball starts from rest and rolls without slipping down a hill. The radius of the...

A basketball starts from rest and rolls without slipping down a hill. The radius of the basketball is 0.23 m, and its 0.625 kg mass is evenly distributed in its thin shell. The hill is 50 m long and makes an angle of 25° with the horizontal. How fast is it going at the bottom of the hill? Group of answer choices 10.7 m/s 12.3 m/s 15.8 m/s 14.4 m/s 17.2 m/s

A basketball starts from rest and rolls without slipping down a hill. The radius of the...

A basketball starts from rest and rolls without slipping down a hill. The radius of the basketball is 0.23 m, and its 0.625 kg mass is evenly distributed in its thin shell. The hill is 50 m long and makes an angle of 25° with the horizontal. How fast is it going at the bottom of the hill? Group of answer choices 17.2 m/s 14.4 m/s 10.7 m/s 12.3 m/s 15.8 m/s

A 1.6 m radius cylinder with a mass of 8.6 kg rolls without slipping down a...

A 1.6 m radius cylinder with a mass of 8.6 kg rolls without slipping down a hill which is 5.6 meters high. At the bottom of the hill, what percentage of its total kinetic energy is invested in rotational kinetic energy?

The sturdy uniform sphere rolled down the 35 m high hill. The ball rolls without slipping,...

The sturdy uniform sphere rolled down the 35 m high hill. The ball rolls without slipping, and there is no external force. What is the linear velocity of the sphere when it reaches the bottom of the mountain?

A hollow spherical shell with mass 2.45 kg rolls without slipping down a slope that makes...

A hollow spherical shell with mass 2.45 kg rolls without slipping down a slope that makes an angle of 30.0 degrees with the horizontal. Find the minimum coefficient of friction μ needed to prevent the spherical shell from slipping as it rolls down the slope.

A spherical shell and thin cylindrical shell with the same mass and radius roll at the...

A spherical shell and thin cylindrical shell with the same mass and radius roll at the same velocity side by side on a level surface without slipping. If the two objects subsequently approach and roll up an inclined plane without slipping, how much higher will the cylindrical shell go before they both stop?

A 0.38 kg playground ball with a 12.0 cm radius rolls without slipping down a pool...

A 0.38 kg playground ball with a 12.0 cm radius rolls without slipping down a pool slide from a vertical distance h1= 2.2 m above the bottom of the slide and then falls an additional h2= 0.40 m vertical distance into the water. What will be the magnitude of the ball's translational velocity when it hits the water? Since the ball is air-filled, assume it approximates a hollow, thin spherical shell. Also, assume that its rate of rotation remains constant...

A hollow spherical shell with mass 2.35 kg rolls without slipping down a slope that makes...

A hollow spherical shell with mass 2.35 kg rolls without slipping down a slope that makes an angle of 35.0 ? with the horizontal. Find the magnitude of the acceleration acm of the center of mass of the spherical shell. Take the free-fall acceleration to be g = 9.80 m/s2 .Find the magnitude of the frictional force acting on the spherical shell. Take the free-fall acceleration to be g = 9.80 m/s2 .