The figure below shows an object of mass m=3.7 kg which is connected to a string...

object of mass m=3.8 kg which is connected to a string of length r=1.20 m. When...

object of mass m=3.8 kg which is connected to a string of length r=1.20 m. When the object is at the bottom of the circle it has velocity vb =10.2 m/s. What is the tension in the string at the top of the circle?

A mass of 3 kg is connected to a string of length 3.4 meters to form...

A mass of 3 kg is connected to a string of length 3.4 meters to form a yo-yo. It is swung in a vertical circle. The string breaks when the tension in the string is 89 Newtons. It happens to reach this tension on the side of the circle (halfway between the top and bottom) and the mass moves through midair at the velocity it was moving at the side when the string broke. What is the maximum vertical displacement...

A tennis ball connected to a string is spun around in a vertical, circular path at...

A tennis ball connected to a string is spun around in a vertical, circular path at a uniform speed. The ball has a mass m = 0.154 kg and moves at v = 5.16 m/s. The circular path has a radius of R = 1.01 m 1) What is the magnitude of the tension in the string when the ball is at the bottom of the circle? 2) What is the magnitude of the tension in the string when the...

1. An object of mass 1.2 kg is attached to a string of 0.83 m. When...

1. An object of mass 1.2 kg is attached to a string of 0.83 m. When this object is rotated around a horizontal circle, it completes 15 revolutions in 9.6 seconds. a. What is the period (T) of this motion? b. What is the tangential velocity of the object? c. What is the tension on the string? Hint: The tension on the string is the centripetal force that causes the circular motion.

The figure below shows a mass m1=5.2 kg moving with velocity v1=47.6 m/s which collides with...

The figure below shows a mass m1=5.2 kg moving with velocity v1=47.6 m/s which collides with a mass m2=3.8 kg which is initially at rest. The collision is completely inelastic and the masses slide up a frictionless hill of mass of height h=11.1 m. What is the kinetic energy K of the masses when they reach the top of the hill. K=727 J K=3879 J K=2425 J K=2061 J K=1576 J

The figure below shows a mass m1=5.1 kg moving with velocity v1=41.6 m/s which collides with...

The figure below shows a mass m1=5.1 kg moving with velocity v1=41.6 m/s which collides with a mass m2=2.6 kg which is initially at rest. The collision is completely inelastic and the masses slide up a frictionless hill of mass of height h=9.8 m. What is the kinetic energy K of the masses when they reach the top of the hill. K=655 J K=3493 J K=1419 J K=2183 J K=1856 J

In the figure below the two blocks are connected by a string of negligible mass passing...

In the figure below the two blocks are connected by a string of negligible mass passing over a frictionless pulley. m1 = 10.0 kg and m2 = 5.50 kg and the angle of the incline is θ = 39.0°. Assume that the incline is smooth. (Assume the +x direction is down the incline of the plane.) (a) With what acceleration (in m/s2) does the mass m2 move on the incline surface? Indicate the direction with the sign of your answer....

A ball with a mass of 1.50 kg is attached to the end of a string...

A ball with a mass of 1.50 kg is attached to the end of a string that is 0.400 m in length. You swing the ball so that it swings in a vertical circle, traveling at a speed of 4.80 m/s at the top of the circle. (a) Draw the free-body diagram of the ball. Make sure you label all your vectors and clearly indicate their direction. (b) What is the tension in the string when the ball is at...

Th figure below shows a mass m=1.0 kg which is initially moving with speed v=6.8 m/s...

Th figure below shows a mass m=1.0 kg which is initially moving with speed v=6.8 m/s at the top of a frictionless hill of height h=4.4 m. It slides down the hill until it encounters a flat section with coefficient of kinetic friction µk=0.8. Find the distance D the object travels before coming to a stop.

An object with a mass of m = 5.5 kg is attached to the free end...

An object with a mass of m = 5.5 kg is attached to the free end of a light string wrapped around a reel of radius R = 0.260 m and mass of M = 3.00 kg. The reel is a solid disk, free to rotate in a vertical plane about the horizontal axis passing through its center as shown in the figure below. The suspended object is released from rest 6.40 m above the floor. (a) Determine the tension...