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Momentum=mass*velocity
One is that the centripetal force (f) created by the rotating mass (m) at a radius (r) can be calculated if the velocity (v) is known. . f (newtons)= m * (v2 / r)
u go girl
An object that is rotating at constant angular velocity will remain rotating unless it is acted upon by an external torque.
The difference between an object's speed and an object's velocity is that the object's speed is how fast it is going, and the object's velocity is how many units of speed the object has traveled.
Momentum=mass*velocity
One is that the centripetal force (f) created by the rotating mass (m) at a radius (r) can be calculated if the velocity (v) is known. . f (newtons)= m * (v2 / r)
u go girl
The tangential velocity is greater as the radius of the point on the rotating object increases. For a rotating object v = rw Where v is the tangential velocity r is the radius of the point And "w" is omega or angular velocity (in radians per second)
accleration is the speed. Velocity is when you know the speed of an object and its direction.
Momentum=mass*velocity
An object that is rotating at constant angular velocity will remain rotating unless it is acted upon by an external torque.
A rotating object.
The difference between an object's speed and an object's velocity is that the object's speed is how fast it is going, and the object's velocity is how many units of speed the object has traveled.
The more massive the object is, or the faster the object is moving, the bigger the crater will be.
Newton's first Law (The velocity of an object remains constant unless...) does apply to rotating objects, but the fact that an object is rotating is not specially relevant to application of the First Law.
The more the mass, the more momentum you will need for an object to speed up more, or accelerate.