Copyright © Michael Richmond.
This work is licensed under a Creative Commons License.
We can also look at rolling motion as a consequence of the torque on an object as it moves down a slope. Consider this ball rolling down a ramp:
Gravity exerts a force F = mg on the center of the ball, directed vertically downwards. Now, if the ball is rolling without slipping, that means that the portion of the ball which touches the ramp is -- for a moment -- motionless. The ball rotates around this point of contact.
Therefore, we can look at the torque exerted around this point of contact by the force of gravity. Let's zoom in ...
Q: What is the torque around the point of contact?
Provide both a magnitude and a direction.
Q: Express this torque in terms of the mass of the
ball, M, and the radius of the ball, R.
Now, how does the ball respond to this torque? Well, it has some moment of inertia, I, so the torque causes it to change its angular velocity. In fact, the angular acceleration must be
Q: Place the expression you derived for the magnitude
of the torque in the top of this equation, and
insert the moment of inertia of a solid sphere in
the bottom of the expression.
What is the angular acceleration?
Copyright © Michael Richmond.
This work is licensed under a Creative Commons License.