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The whirlpool's centripetal motion created a vortex that pulled Captain Ahab's ship underwater, causing its destruction. This powerful force is known for its ability to create a swirling motion that can be dangerous for objects caught in its path.
The direction of the centripetal acceleration vector in circular motion is towards the center of the circle.
The centripetal force is always perpendicular to the motion in circular motion. It acts towards the center of the circle, keeping the object moving in a circular path.
In circular motion, centripetal force is the force that keeps an object moving in a circle. The centripetal force is directly proportional to the velocity of the object in circular motion. This means that as the velocity of the object increases, the centripetal force required to keep it moving in a circle also increases.
In circular motion, centripetal acceleration is directly proportional to angular velocity. This means that as the angular velocity increases, the centripetal acceleration also increases.
The whirlpool's centripetal motion created a vortex that pulled Captain Ahab's ship underwater, causing its destruction. This powerful force is known for its ability to create a swirling motion that can be dangerous for objects caught in its path.
The centripetal force
The direction of the centripetal acceleration vector in circular motion is towards the center of the circle.
The centripetal force is always perpendicular to the motion in circular motion. It acts towards the center of the circle, keeping the object moving in a circular path.
In circular motion, centripetal force is the force that keeps an object moving in a circle. The centripetal force is directly proportional to the velocity of the object in circular motion. This means that as the velocity of the object increases, the centripetal force required to keep it moving in a circle also increases.
In circular motion, centripetal acceleration is directly proportional to angular velocity. This means that as the angular velocity increases, the centripetal acceleration also increases.
Basically, the centripetal force CAUSES the circular motion in the first place. In other words, without a centripetal force, the moving object would just go straight ahead.
Centripetal acceleration at a constant velocity and projectile motion are realistic comparisons, but only in this particular scenario. It should be noted that the vector quantity of both needs to be taken into consideration when answering this question. The vector component of centripetal acceleration moves inward, while outward for projectile motion. So, in essence, centripetal acceleration and projectile motion are not the same thing.
Centripetal acceleration can be changed by altering the speed or direction of an object in circular motion. Increasing the speed will increase the centripetal acceleration, while changing the direction of motion will also change the centripetal acceleration.
The formula for calculating centripetal acceleration in terms of the radius of the circular motion is a v2/r, where "a" represents the centripetal acceleration, "v" is the velocity of the object in circular motion, and "r" is the radius of the circle.
Centripetal kinetic energy is the energy associated with an object's motion in a circular path. It is directly related to the speed and mass of the object, as well as the radius of the circular path. As the object moves in a circular motion, centripetal kinetic energy is constantly changing to keep the object moving in a curved path.
An object in uniform motion does not experience centripetal force. Centripetal force is only present when an object is moving in a circular path, causing it to change direction. Uniform motion refers to constant velocity in a straight line without any change in speed or direction.