Gravity
The force acting on the ball as it moves down the slope is the gravitational force, which pulls the ball downward towards the center of the Earth. Additionally, there may be a component of the force due to friction between the ball and the surface of the slope, which opposes the motion of the ball.
The centripetal force, directed towards the center of the circle, keeps the ball on a string moving in a circle. This force is provided by the tension in the string, which constantly pulls the ball towards the center, preventing it from moving in a straight line. The ball's velocity remains tangential to the circle due to the centripetal force acting perpendicular to the velocity vector, resulting in circular motion.
The net force would be in the direction of the bowling ball's motion, which in this case would be towards the bowling pin.
The magnitude of the tension in the string at the bottom of the circle is equal to the sum of the gravitational force acting on the ball and the centripetal force required to keep the ball moving in a circular path.
When a ball is pushed uphill, the main forces acting on it are the force applied by the person pushing the ball, which is in the direction of motion, and the force of gravity acting against the motion of the ball, which is pulling it downhill. Friction between the ball and the surface it is moving on also plays a role in resisting the motion.
The force acting on the ball as it moves down the slope is the gravitational force, which pulls the ball downward towards the center of the Earth. Additionally, there may be a component of the force due to friction between the ball and the surface of the slope, which opposes the motion of the ball.
Inthe kicking force, kinetic energy is acting on the ball together with Gravitational Potential Energy. Whereas the part where aother force is acting on iit while the ball is not moving is alsoocontrolled by gravitaitional potential energy.
The centripetal force, directed towards the center of the circle, keeps the ball on a string moving in a circle. This force is provided by the tension in the string, which constantly pulls the ball towards the center, preventing it from moving in a straight line. The ball's velocity remains tangential to the circle due to the centripetal force acting perpendicular to the velocity vector, resulting in circular motion.
We might say that an unbalanced force causes a ball to start moving. If a ball is resting on a surface, gravity is pulling down and the surface is pushing up against it. Things (forces) are in balance and the ball is still. Drop the surface out from under the ball and that ball begins to fall as gravity has no opposing force to balance it.Any lateral force on the ball that can overcome its rolling resistance will cause the ball to move. The inertia of the ball is such that it "wants" to remain at rest. Some unbalanced force will have to act on the ball to cause it to start moving. A ball on a pool table sits still until struck by a cue or another ball. It takes an "outside" force to "unbalance" the forces acting on a ball that is at rest to cause it to move.
The net force would be in the direction of the bowling ball's motion, which in this case would be towards the bowling pin.
The magnitude of the tension in the string at the bottom of the circle is equal to the sum of the gravitational force acting on the ball and the centripetal force required to keep the ball moving in a circular path.
When a ball is pushed uphill, the main forces acting on it are the force applied by the person pushing the ball, which is in the direction of motion, and the force of gravity acting against the motion of the ball, which is pulling it downhill. Friction between the ball and the surface it is moving on also plays a role in resisting the motion.
The force of gravity is acting on the ball immediately after you let go of it.
The force that keeps a ball moving in a circle is called centripetal force. This force acts towards the center of the circle and prevents the ball from moving in a straight line.
To calculate the force acting on the ball from the floor, you need to use Newton's second law of motion, which states that force equals mass times acceleration. Acceleration can be calculated as the slope of the velocity-time graph. Given the mass of the ball, you can calculate the force acting on it using this formula.
No, centripetal force is not acting when a body is moving in a straight line. Centripetal force is required to keep an object moving in a curved path.
When it stops it stops. Inertia will stop it from moving unless there is some force acting on it.