In an Atwood's machine, one block has a mass of 498.0 g, and the other a...

In an Atwood's machine, one block has a mass of 346.0 g, and the other a...

In an Atwood's machine, one block has a mass of 346.0 g, and the other a mass of 526.0 g. The pulley, which is mounted in horizontal frictionless bearings, has a radius of 4.50 cm. When released from rest, the heavier block is observed to fall 64.2 cm in 2.29 s (without the string slipping on the pulley). What is the magnitude of the acceleration of the 346.0-g block? What is the magnitude of the acceleration of the 526.0-g block?...

In an Atwood's machine, one block has a mass of 860.0 g, and the other a...

In an Atwood's machine, one block has a mass of 860.0 g, and the other a mass of 1020.0 g. The pulley, which is mounted in horizontal frictionless bearings, has a radius of 4.50 cm. When released from rest, the heavier block is observed to fall 62.2 cm in 2.55 s (without the string slipping on the pulley). What is the magnitude of the acceleration of the 860.0-g block?   Tries 0/16 What is the magnitude of the acceleration of the...

An Atwood's machine consists of blocks of masses m1 = 13.0 kg and m2 = 19.0...

An Atwood's machine consists of blocks of masses m1 = 13.0 kg and m2 = 19.0 kg attached by a cord running over a pulley as in the figure below. The pulley is a solid cylinder with mass M = 9.20 kg and radius r = 0.200 m. The block of mass m2 is allowed to drop, and the cord turns the pulley without slipping. (a) Why must the tension T2 be greater than the tension T1? This answer has...

(Figure 1) illustrates an Atwood's machine. Let the masses of blocks A and B be 7.50...

(Figure 1) illustrates an Atwood's machine. Let the masses of blocks A and B be 7.50 kg and 1.50 kg , respectively, the moment of inertia of the wheel about its axis be 0.220 kg⋅m2, and the radius of the wheel be 0.120 m. There is no slipping between the cord and the surface of the wheel. Part A Find the magnitude of the linear acceleration of block A. Express your answer with the appropriate units. Part B Find the...

An Atwood's machine consists of blocks of masses m1 = 12.0 kg and m2 = 22.0...

An Atwood's machine consists of blocks of masses m1 = 12.0 kg and m2 = 22.0 kg attached by a cord running over a pulley as in the figure below. The pulley is a solid cylinder with mass M = 7.60 kg and radius r = 0.200 m. The block of mass m2 is allowed to drop, and the cord turns the pulley without slipping. Two objects, blocks labeled m1 and m2, are connected to a cord which is hung...

The figure shows two blocks connected by a cord (of negligible mass) that passes over a...

The figure shows two blocks connected by a cord (of negligible mass) that passes over a frictionless pulley (also of negligible mass). The arrangement is known as Atwood's machine. Block 1 has mass m1 = 2.20 kg; block 2 has mass m2 = 4.60 kg. What are (a) the magnitude of the blocks’ acceleration and (b) the tension in the cord?

A block (mass = 1.2 kg) is hanging from a massless cord that is wrapped around...

A block (mass = 1.2 kg) is hanging from a massless cord that is wrapped around a pulley (moment of inertia = 1.0 x 10-3 kg·m2), as the figure shows. Initially the pulley is prevented from rotating and the block is stationary. Then, the pulley is allowed to rotate as the block falls. The cord does not slip relative to the pulley as the block falls. Assume that the radius of the cord around the pulley remains constant at a...

A block (mass = 3.0 kg) is hanging from a massless cord that is wrapped around...

A block (mass = 3.0 kg) is hanging from a massless cord that is wrapped around a pulley (moment of inertia = 1.2 x 10-3 kg·m2), as the figure shows. Initially the pulley is prevented from rotating and the block is stationary. Then, the pulley is allowed to rotate as the block falls. The cord does not slip relative to the pulley as the block falls. Assume that the radius of the cord around the pulley remains constant at a...

A block (mass = 1.0 kg) is hanging from a massless cord that is wrapped around...

A block (mass = 1.0 kg) is hanging from a massless cord that is wrapped around a pulley (moment of inertia = 1.1 x 10-3 kg·m2), as the figure shows. Initially the pulley is prevented from rotating and the block is stationary. Then, the pulley is allowed to rotate as the block falls. The cord does not slip relative to the pulley as the block falls. Assume that the radius of the cord around the pulley remains constant at a...

A block (mass = 2.3 kg) is hanging from a massless cord that is wrapped around...

A block (mass = 2.3 kg) is hanging from a massless cord that is wrapped around a pulley (moment of inertia = 1.7 x 10-3 kg·m2), as the figure shows. Initially the pulley is prevented from rotating and the block is stationary. Then, the pulley is allowed to rotate as the block falls. The cord does not slip relative to the pulley as the block falls. Assume that the radius of the cord around the pulley remains constant at a...