yes, correctmarvolo1300 said:Thank you PhantomJay.
The centripetal force in this problem is provided by the tension of the string and also the force of gravity.
No, that is not correct. Fnet = mv^2/rSo, Fnet = m*g + (m*v^2)/r
The net force at the bottom of circular motion is the sum of all the forces acting on an object at the bottom of a circular path. This includes the centripetal force, which is directed towards the center of the circle, and any other external forces such as gravity or friction.
The net force at the bottom of circular motion can be calculated using the formula F_net = F_centripetal + F_external, where F_centripetal is the centripetal force and F_external is the sum of all other external forces acting on the object.
No, the net force at the bottom of circular motion is not always zero. It is only zero if the centripetal force is equal in magnitude and opposite in direction to the sum of all other external forces. If this is not the case, there will be a net force acting on the object.
The net force at the bottom of circular motion affects the speed of the object by changing its direction or magnitude. If the net force is directed towards the center of the circle, it will cause the object to continue moving in a circular path at a constant speed. If the net force is not directed towards the center, it will cause the object to speed up or slow down depending on the direction and magnitude of the force.
Yes, the net force at the bottom of circular motion can be greater than the centripetal force. This can happen if the sum of all other external forces is greater than the centripetal force, causing a net force in the direction of those forces. In this case, the object will not move in a circular path and may even accelerate away from the center of the circle.