The pulley has significant friction.

The pulley is frictionless at the axle.

The pulley has a large radius.

The pulley is not rotating.

Because there is no external force applied.

Because the system is isolated in a vacuum.

Because the masses are equal.

Because the pulley is not moving.

The elastic potential energy of a spring.

The kinetic energy of mass 1.

The rotational kinetic energy of the pulley.

The gravitational potential energy of mass 2.

It is twice the linear velocity.

It is equal to the linear velocity divided by the radius.

It is half of the linear velocity.

It is unrelated to the linear velocity.

Arc length equals radius times angular displacement.

Linear distance equals angular velocity times time.

Radius equals arc length divided by time.

Angular displacement equals mass times acceleration.

Pulley radius squared times the sum of masses.

Pulley radius times the sum of masses divided by rotational inertia.

Pulley radius times acceleration due to gravity times the difference in masses divided by the sum of masses and rotational inertia.

Pulley radius times mass 1 divided by mass 2.

Using the law of conservation of momentum.

Using the translational and rotational forms of Newton's second law.

Using the law of universal gravitation.

Using the principle of least action.