What will be the speed of a solid sphere when it reaches the bottom of an...

A solid sphere with a radius 0.25 m and mass 240 g rolls without slipping down...

A solid sphere with a radius 0.25 m and mass 240 g rolls without slipping down an incline, starting from rest from a height 1.0 m. a. What is the speed of the sphere when it reaches the bottom of the incline? b. From what height must a solid disk with the same mass and radius be released from rest to have the same velocity at the bottom? It also rolls without slipping.

A solid cylinder starts from rest at the top of an incline of height h =...

A solid cylinder starts from rest at the top of an incline of height h = 0.7 m and rolls down without slipping. Ignoring friction, determine the speed at the bottom of the incline. Draw and label a figure.

A solid sphere of ice and a solid sphere of plastic are placed at the top...

A solid sphere of ice and a solid sphere of plastic are placed at the top of an inclined plane of length L and simultaneously released from rest, as shown in (Figure 1). Each has mass m and radius R. Assume that the coefficient of friction between the ice sphere and the incline is zero and that the plastic sphere rolls down the incline without slipping. Derive expressions for the following quantities in terms of L, θ, m, and R:...

A solid, homogeneous sphere with of mass of M = 2.25 kg and a radius of...

A solid, homogeneous sphere with of mass of M = 2.25 kg and a radius of R = 11.3 cm is resting at the top of an incline as shown in the figure. The height of the incline is h = 1.65 m, and the angle of the incline is θ = 17.3°. The sphere is rolled over the edge very slowly. Then it rolls down to the bottom of the incline without slipping. What is the final speed of...

A solid sphere of ice and a solid sphere of plastic are placed at the top...

A solid sphere of ice and a solid sphere of plastic are placed at the top of an inclined plane of length L and simultaneously released from rest, as shown in (Figure 1). Each has mass m and radius R. Assume that the coefficient of friction between the ice sphere and the incline is zero and that the plastic sphere rolls down the incline without slipping. Derive expressions for the following quantities in terms of L, θ, m, and R:...

Calculate the translational speed of a cylinder when it reaches the foot of an incline 6.85...

Calculate the translational speed of a cylinder when it reaches the foot of an incline 6.85 m high. Assume it starts from rest and rolls without slipping.

A solid sphere of uniform density starts from rest and rolls without slipping a distance of...

A solid sphere of uniform density starts from rest and rolls without slipping a distance of d = 4.4 m down a θ = 22°incline. The sphere has a mass  M = 4.3 kg and a radius R = 0.28 m. 1)Of the total kinetic energy of the sphere, what fraction is translational? KE tran/KEtotal = 2)What is the translational kinetic energy of the sphere when it reaches the bottom of the incline? KE tran = 3)What is the translational speed...

A solid sphere is rolling (without slipping) at a translational speed of 2 m/s when it...

A solid sphere is rolling (without slipping) at a translational speed of 2 m/s when it approaches an incline. To what vertical height does the sphere roll when it stops? Use I = (2/5)mR^2

A solid sphere of mass 0.6010 kg rolls without slipping along a horizontal surface with a...

A solid sphere of mass 0.6010 kg rolls without slipping along a horizontal surface with a translational speed of 5.420 m/s. It comes to an incline that makes an angle of 31.00° with the horizontal surface. To what vertical height above the horizontal surface does the sphere rise on the incline?

A sphere of mass M, radius r, and rotational inertia I is released from rest at...

A sphere of mass M, radius r, and rotational inertia I is released from rest at the top of an inclined plane of height h as shown above. (diagram not shown) If the plane has friction so that the sphere rolls without slipping, what is the speed vcm of the center of mass at the bottom of the incline?