The circular path that the stone follows is. It takes centripetal force
to move any mass in a circular path.
inertia
No. The force keeping a ball on a string moving in a circle is centripetal force, i.e. force pulling the ball to the center of the circle.
The string
As force acting in a circular path is always tangential to the path
Could be the tension in the string from which it hangs.
Picture a ball on a string being whirled about the head of an experimenter. If the string breaks, the centripetal force disappears. The ball leaves on a tangent path form its (previous) circular path. Yes, it's that simple. The string provided centripetal force, by virtue of its tensile strength, to the ball to keep that ball moving in a circle. When the string broke, there was no force left to accelerate the ball "in" and keep it moving in an arc.
the object will go in its tangential direction of that instant. centripetal force pulls the object toward its rotational axis, so if there is no force pulling it inward; inertia will make the object go in the direction it "wants to go" aka- its tangential direction
A ball on a string is an example of centripetal acceleration
inertia
A ball on a string.
Centripetal force is the force necessary to apply to an object to get it to orbit; like spinning a rock on a string. It you are holding on to the string, you will feel a centrifugal force.
No. The force keeping a ball on a string moving in a circle is centripetal force, i.e. force pulling the ball to the center of the circle.
centripetal
Convert the speed to meters per second. Use the formula acceleration = speed squared / radius to find the centripetal acceleration. Then use the formula force = mass x acceleration to find the corresponding force.
The tension in the string, which prevents the ball continuing forward in a straight line.
I'm not sure exactly what you are asking, but centripetal force is just a name given to any force that causes circular motion. Swing a rock on the end of a string and the string tension is the centripetal force. Drive a car around a flat circular track and the friction between the tires and the road is the centripetal force. Put a satellite in orbit and gravity is the centripetal force.
The string