Net force equals mass times velocity

Net force equals mass times acceleration

Net force equals mass times distance

Net force equals velocity times time

Net torque equals mass times velocity

Net torque equals rotational inertia times angular velocity

Net torque equals mass times angular acceleration

Net torque equals rotational inertia times angular acceleration

Linear momentum

Angular velocity

Net torque

Rotational inertia

Because their magnitudes are equal

Because they have the same direction

Because the area of the parallelogram they form is zero

Because they are perpendicular

As the difference between position vector and linear momentum

As the product of mass and velocity

As the cross product of position vector and linear momentum

As the sum of position vector and linear momentum

Torque is the product of angular momentum and time

Torque is the integral of angular momentum with respect to time

Torque is the sum of angular momentum and time

Torque is the derivative of angular momentum with respect to time

Yes, it can have angular momentum relative to any point

No, it needs a rigid body

Only if it is moving in a circle

Only if it is at rest