What is centripetal force derive an expression for it show that centripetal force does no work

Force is required to make an object move, and force acts differently on objects depending on the type of motion it exhibits. In the case of curvilinear motion, a special force comes into the picture, i.e., centripetal force – literally meaning “centre seeking.” Centripetal force is the force acting towards the centre of the circular path. In this article, let us discuss what centripetal force is and how it is different from centrifugal force.

Table of Contents Show

Centrifugal force and Newton's laws of motion
Examples of centripetal force
Additional resources
Bibliography

According to the centripetal force definition,

Centripetal force is the force acting on an object in curvilinear motion directed towards the axis of rotation or centre of curvature.

The unit of centripetal force is newton.

The centripetal force is always directed perpendicular to the direction of the object’s displacement. Using Newton’s second law of motion, it is found that the centripetal force of an object moving in a circular path always acts towards the centre of the circle.

The Centripetal Force Formula is given as the product of mass (in kg) and tangential velocity (in meters per second) squared, divided by the radius (in meters) that implies that on doubling the tangential velocity, the centripetal force will be quadrupled. Mathematically it is written as:

\(\begin{array}{l}F=\frac{mv^{2}}{r}\end{array} \)

Where, F is the Centripetal force, m is the mass of the object, v is the speed or velocity of the object and r is the radius.

The centripetal force pulls or pushes an object towards the centre of a circle as it travels, causing angular or circular motion.

When spinning a ball on a string or twirling a lasso, the force of tension on the rope pulls the object towards the centre.
The centripetal force is provided by the frictional force between the ground and the wheels when turning a car.
When going through a loop on a roller coaster, the force is provided by the normal force as the seat or wall pushes you towards the centre.
For the planets orbiting around the Sun, the centripetal force is provided by Gravity.

Watch the video and understand what keeps the moon in orbit around the earth.

Centrifugal force is a pseudo force in a circular motion which acts along the radius and is directed away from the centre of the circle. The force does not exist when measurements are made in an inertial frame of reference. It only comes into play when changing our reference frame from a ground/inertial to a rotating reference frame.

The centrifugal force’s unit is newton.

A centrifugal force basically uses the centripetal force formula (which describes a real phenomenon) and reverses the direction of the force, to describe the fictitious centrifugal force.

\(\begin{array}{l}F=-\frac{mv^{2}}{r}\end{array} \)

Where, F is the Centrifugal force, m is the mass of the object, v is the speed or velocity of the object and r is the radius.

Centrifugal Force acts on every object moving in a circular path when viewed from a rotating frame of reference. Some examples of Centrifugal Force are given below.

Weight of an object at the poles and on the equator
A bike making a turn.
Vehicle driving around a curve
Equatorial railway

Check the table below to learn the detailed comparison between Centripetal and Centrifugal Force

Differences Between Centripetal And Centrifugal Force
Centripetal Force	Centrifugal Force
Centripetal force is the component of force acting on an object in curvilinear motion which is directed towards the axis of rotation or centre of curvature.	Centrifugal force is a pseudo force in a circular motion which acts along the radius and is directed away from the centre of the circle.
It is observed from an inertial frame of reference.	It is observed from a non-inertial frame of reference.
If a car is travelling through a curve on a circular horizontal road, the centripetal force provided by the force of friction between the tyres of the vehicle and the road surface allows the car to negotiate the turn.	When a car in motion takes a sudden turn towards the left, passengers in a car experience an outward push. This is due to the centrifugal force acting on passengers.

Centripetal force is the component of force acting on an object in curvilinear motion which is directed towards the axis of rotation or centre of curvature.

The revolution of the moon around the earth and the spinning of the top are some examples of centripetal force.

Yes! The expression for centripetal force is given by mv2/R. This suggests as the speed of the particle increases, so does the centripetal force experienced by it.

No! The expression for centripetal force is given by mv2/R. This suggests as the radius of the turn of the particle increases, the centripetal force experienced by it decreases.

Centripetal force is observed from an inertial frame of reference, while centrifugal force is observed from a non-inertial frame of reference. Centripetal force is directed towards the axis of rotation or centre of curvature, and centrifugal force is directed away from the centre of the circle.

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Centripetal and centrifugal forces are the forces experienced by rotating objects. The centripetal force keeps an object moving in a circle and is always pointed toward the center of that circle. For instance, the gravitational force of the sun is a centripetal force that keeps the Earth orbiting around it. Meanwhile, the centrifugal force is an apparent outward force on an object that is moving in a circle. An example of centrifugal force would be the sensation you have when riding a merry-go-round that makes you want to fly outwards.

The main difference between centripetal and centrifugal forces is that the centripetal force is the force pointing towards the center of a circle that keeps an object moving in a circular path, while the centrifugal force is the sensation that an object feels when it moves in that circular path, with that sensation seeming to push it away from the center of a circle.

People experience centrifugal force when they round a corner in a car or when an airplane banks into a turn. It occurs in the spin cycle of a washing machine or when children ride on a merry-go-round. One day it may even provide artificial gravity for spaceships and space stations - if we can get spacecraft to spin rapidly enough, the centrifugal force can provide some semblance of the normal sensation of gravity.

But centrifugal force is often confused with its counterpart, centripetal force, because they are so closely related — essentially two sides of the same coin.

Centripetal force is the name given to any force that keeps an object moving in a circle — think of a rock tied to the end of a string, with the other end tied to something or in your hand. When the string is swirled around, the tension in that string keeps the rock from flying away in a straight line. That tension points inward, toward the center of the circle. As another example, the sun’s gravity provides the centripetal force that keeps the planets moving in their orbits.

The centripetal force always points perpendicular to the direction of an object’s motion. If you're riding in a car and the road banks and curves to the left, the normal force from the banked road will push the car to the left. If the centripetal force were to suddenly disappear, the car would continue moving in a straight line.

On the other hand, centrifugal force is an apparent force that an object feels as it moves along a curved path — and that apparent force is pointed in a direction away from the center of the path of rotation, according to Christopher S. Baird at West Texas A&M University (opens in new tab).

Centrifugal is the outward force while centripetal pulls a rotating object inward. (Image credit: Future)

Note that while centripetal force is an actual force, centrifugal force is defined as an apparent force. In other words, when twirling a mass on a string, the string exerts an inward centripetal force on the mass, while mass "appears" to exert an outward centrifugal force on the string.

"The difference between centripetal and centrifugal force has to do with different 'frames of reference,' that is, different viewpoints from which you measure something," said Andrew A. Ganse, a research physicist at the University of Washington. "Centripetal force and centrifugal force are really the exact same force, just in opposite directions because they're experienced from different frames of reference."

If you are observing a rotating system from the outside, you see an inward centripetal force acting to constrain the rotating body to a circular path. However, if you are part of the rotating system, you experience an apparent centrifugal force pushing you away from the center of the circle, even though what you are actually feeling is the inward centripetal force that is keeping you from literally going off on a tangent.

Let's return to the example of the car following a banked turn. If you're watching from the outside, you can observe the centripetal force pushing the car inward toward the center, keeping it moving in a circle. But if you're riding inside the car, you instead feel a force attempting to push you away from the center of the circle — this is the centrifugal force.

Centrifugal force and Newton's laws of motion

This apparent outward force is described by Newton's laws of motion. Newton's first law states that "a body at rest will remain at rest, and a body in motion will remain in motion unless it is acted upon by an external force."

If a massive body is moving through space in a straight line, its inertia will cause it to continue in a straight line unless an outside force causes it to speed up, slow down or change direction. In order for it to follow a circular path without changing speed, a continuous centripetal force must be applied at a right angle to its path. The radius (r) of this circle is equal to the mass (m) times the square of the velocity (v) divided by the centripetal force (F), or r = mv^2/F. The force can be calculated by simply rearranging the equation — F= mv^2/r.

Newton's third law states that "for every action, there is an equal and opposite reaction." Just as gravity causes you to exert a force on the ground, the ground appears to exert an equal and opposite force on your feet. When you are in an accelerating car, the seat exerts a forward force on you just as you appear to exert a backward force on the seat.

In the case of a rotating system, the centripetal force pulls the mass inward to follow a curved path, while the mass appears to push outward due to its inertia. In each of these cases, though, there is only one real force being applied, while the other is only an apparent force.

Examples of centripetal force

There are many applications that exploit centripetal force. One is to simulate the acceleration of a space launch for astronaut training. When a rocket is first launched, it is so laden with fuel and oxidizer that it can barely move. However, as it ascends, it burns fuel at a tremendous rate, continuously losing mass. Newton's second law states that force equals mass times acceleration, or F = ma.

In most situations, mass remains constant. With a rocket, though, its mass changes drastically, while the force — in this case the thrust of the rocket motors — remains nearly constant. This causes the acceleration toward the end of the boost phase to increase to several times that of normal gravity. NASA uses large centrifuges (opens in new tab) to prepare astronauts for this extreme acceleration. In this application, the centripetal force is provided by the back of the seat pushing inward on the astronaut.

Laboratory centrifuges spin rapidly and exert centripetal force on liquids such as blood, which are then separated based on their density. (Image credit: Shutterstock)

Another example of the application of centripetal force is in laboratory centrifuges, which are used to accelerate the precipitation of particles suspended in liquid. One common use of this technology is for preparing blood samples for analysis. According to Rice University's Experimental Biosciences website (opens in new tab), "The unique structure of blood makes it very easy to separate red blood cells from plasma and the other formed elements by differential centrifugation."

Under the normal force of gravity, thermal motion causes continuous mixing, which prevents blood cells from settling out of a whole blood sample. However, a typical laboratory centrifuge can achieve accelerations that are 600 to 2,000 times that of normal gravity. This forces the heavy red blood cells to settle at the bottom and stratifies the various components of the solution into layers according to their density.

This article was updated on Nov 11, 2021 by Live Science editor, Ben Biggs.

Additional resources

You can read more about the basics of centripetal force from the Swinburne University of Technology (opens in new tab). SciShow provides a great video introduction to the topic where they explain and compare centripetal and centrifugal forces (opens in new tab). And Khan Academy offers (opens in new tab) a mathematical discussion of the topic in this article.