A 1.08 kg hollow ball with radius of 0.12 m is filled with air and is...

A hollow ball of mass 2.88 kg and radius 0.309 m sits at rest on top...

A hollow ball of mass 2.88 kg and radius 0.309 m sits at rest on top of a hill of height 6.88 m. The ball can either slide down the hill without rolling or roll down without slipping. What is the difference in the ball's speed (in m/s) at the bottom of the hill between these two scenarios?

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 10 kg ball with a radius of 0.6 m rolls down a hill which...

​A hollow 10 kg ball with a radius of 0.6 m rolls down a hill which is 50 m high and 100 m long. ​How fast is the ball going at the bottom of the hill if it starts from rest? Moment of inertia for a ​hollow ball: 1 = (2mr2)/3

A 1.90 kg solid, uniform ball of radius 0.200 m is released from rest at point...

A 1.90 kg solid, uniform ball of radius 0.200 m is released from rest at point A in the figure below, its center of gravity a distance of 1.70 m above the ground. The ball rolls without slipping to the bottom of an incline and back up to point B where it is launched vertically into the air. The ball then rises to its maximum height hmax at point C. HINT 1.70 m0.450 m (a) At point B, find the...

A hollow ball of mass 6.00 kg and radius 0.180 m is rolled up a hill...

A hollow ball of mass 6.00 kg and radius 0.180 m is rolled up a hill without slipping. If it starts off at the bottom with a linear speed of 7.00 m/s, what vertical height (in m) will it reach?

A ball of mass 0.40 kg is fired with velocity 200 m/s into the barrel of...

A ball of mass 0.40 kg is fired with velocity 200 m/s into the barrel of a spring gun of mass 1.5 kg initially at rest on a frictionless surface. The ball sticks in the barrel at the point of maximum compression of the spring. No energy is lost to friction. What fraction of the ball's initial kinetic energy is stored in the spring?

The spaceship S. Lem lands on Solaris (mass 4.04x1024 kg, radius 7.27x107 m, air pressure 1.22x105Pascal)....

The spaceship S. Lem lands on Solaris (mass 4.04x1024 kg, radius 7.27x107 m, air pressure 1.22x105Pascal). The crew discovers pools of a mysterious substance of specific gravity 13.5. Find the pressure at the bottom of one pool of this substance, 90.9 m deep, in Pascals. Express your answer in scientific notation.

A solid sphere of mass 4.0 kg and radius 0.12 m starts from rest at the...

A solid sphere of mass 4.0 kg and radius 0.12 m starts from rest at the top of a ramp inclined 15 degrees and rolls to the bottom. The upper end of the ramp is 2.0 m higher than the lower end. What is the linear velocity when it reaches the bottom of the ramp? A. 4.7 m/s B. 4.1 m/s C. 3.4 m/s D. 5.3 m/s E. 1.8 m/s

1. The three tanks shown above are filled with water to an equal depth. All the...

1. The three tanks shown above are filled with water to an equal depth. All the tanks have an equal height. Tank A has the least surface area at the bottom, tank B has the greatest and tank C has the middle area at the bottom. (Select T-True, F-False, G-Greater than, L-Less than, E-Equal to. If the first is F the second L and the rest G, enter FLGGGG). A) The total force exerted by the water on the bottom...

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