0.0385 kg·m²

0.200 kg·m²

0.0137 kg·m²

0.100 kg·m²

Because the pulley is frictionless

Because the pulley has mass and rotational inertia

Because the string is elastic

Because the masses are equal

Downward

Clockwise

Upward

Counterclockwise

Using the sum of torques

Using the mass of the pulley

Using the initial velocity

Using the sum of forces

2.43 radians/s²

4.00 radians/s²

3.21 radians/s²

2.67 radians/s²

3.21 N

0.991 N

1.94 N

2.67 N

2.67 N

0.991 N

3.21 N

1.94 N

Because the masses do not have rotational inertia

Because the pulley is not rotating

Because the pulley has no friction

Because the masses have rotational inertia

The forces of tension would be different

The forces of tension would be the same

The string would break

The pulley would not rotate

The string has no tension

The pulley does not rotate

The axle of the pulley has negligible friction

The string slides on the pulley