Torque and centripetal force serve distinct roles in rotational dynamics. Torque causes an object to rotate about its own axis, while centripetal force enables an object to revolve around an external axis. For instance, when a force is applied to a rod, it rotates about its center of mass due to torque, whereas a ball on a string revolves around a person due to centripetal force without rotating about its own center. The discussion clarifies that the key difference lies in the axis of rotation and the nature of motion involved.
PREREQUISITESPhysics students, educators, and anyone interested in understanding the principles of rotational dynamics and the distinctions between torque and centripetal force.
I don't think that statement makes sense. For a circular motion, there has to be a centripetal force, but that can come from anywhere.while centripetal force causes a system to rotate about the axis of the separate system that exerted the centripetal force.
mfb said:I don't think that statement makes sense. For a circular motion, there has to be a centripetal force, but that can come from anywhere.
What does "cause rotation" or "cause revolution" mean?
The difference is just the axis of rotation.PPERERA said:What I was trying to do was to see if there was a distinction between revolution (an object is in circular motion around another object that is not in circular motion) and rotation (an object in circular motion about an axis within itself) that could be explained by rotational dynamics.
It would rotate around its center of mass, but it would also produce translational motion.PPERERA said:A force is applied to the end of the rod. In this situation, I would expect the rod to being to rotate about the axis going through its center of mass as a result of the applied torque only.
Internally in the rod, sure, as the outer parts do not move in a straight line.PPERERA said:And if the rod begins to rotate, is there a centripetal force involved?
Oh, it would, at the same angular frequency as the rotation around the other end of the string, otherwise the string starts to roll up and that provides a torque.PPERERA said:Because there is no torque applied on the ball, the ball does not rotate about its center of mass
The change in linear momentum of the rod equals the impulse (force x time) applied to the rod. The applied torque equals force x radius (distance from point of application to center of mass of the rod), and the change in angular momentum = torque x time.PPERERA said:A force is applied to the end of the rod.
In order to get the ball moving or to change speed, a force in the direction of the velocity of the ball is required. The person does this by initially pulling on his / her end of the string, then twirling his / her end of the string in a circular path that is "ahead" of the path of the ball.PPERERA said:Now clear your mind and imagine a ball attached to a string at a fixed position.
If think the difference the OP means is between rotation (changing orientation) and circular motion (translation alongmfb said:The difference is just the axis of rotation.
You can view any rotating rigid body as a collection point masses in circular translatory motion.PPERERA said:What I was trying to do was to see if there was a distinction between revolution (an object is in circular motion around another object that is not in circular motion) and rotation (an object in circular motion about an axis within itself) that could be explained by rotational dynamics.