# What is the difference between kinetic and potential energy

Kinetic energy is the energy of movement. Potential energy is stored energy that can be converted into kinetic or other forms of energy. Kinetic and potential energies are very closely linked to one another, but they’re not quite the same thing.

The two types of energies are related because kinetic always equals to minus-potential, so when something has more potential it also has less kinetic and vice versa.

Kinetic can never exceed negative-potential, while potential could go up infinitely high without limit because it’s just a matter of storing more and more in an object until its weight pulls down on it too much for any more to fit inside.

## What is an example of potential energy and kinetic energy?  Potential energy is the stored energy in an object that can be converted to kinetic energy. An example of potential and kinetic energies would be a ball on top of a hill.

The ball has potential energy but it does not have any kinetic energy because it is at rest, so all its stored up power just sits there waiting for something to happen.

When you roll the ball down the slope, gravity takes over and starts converting that potential into kinetic – this happens because when the ball moves, friction between the ground and the surface causes heat which turns into movement or momentum!

## What are 2 examples of potential energy?  There are many examples of potential energy that we encounter in our everyday lives. One example is gravity. The gravitational pull from the earth has a lot of potential to move things, including people and objects on the ground, if they have enough kinetic energy or momentum.

Another example is when you step off a diving board at a pool: your body’s weight creates a force with the ground below it which is called gravitational potential energy, and this helps propel yourself into space during flight so you can dive in for a swim!

## What is kinetic and potential energy in simple words?

Kinetic and potential energy are two types of energy that exist in most objects. Kinetic energy is the movement of an object, while potential energy is stored by an object.

For example, if you jump off a table your kinetic (movement) will increase as you fall down to the ground, but your potential (stored) will decrease because gravity is pulling you towards it.

So when we say “kinetic” or “potential,” they both mean different things about how fast something moves or what its position in space might be.

## What is the formula of kinetic and potential energy?

This blog post is going to discuss the formula of kinetic and potential energy. Kinetic energy is always conserved, which means it can’t be created or destroyed. Potential energy is what you have when you lift a rock off the ground- gravity creates this type of potential energy.

It takes more work to move fast than slow because moving slowly does not require much force but moving quickly requires a lot of force.

The equation for kinetic and potential energy is KE=1/2m*v^2+PE, where m is mass in kilograms, v represents speed in meters per second, and PE stands for “potential” as well as “energy.” This equation has been used by scientists around the world for many years now!

## What is the relationship between potential and kinetic energy?

The relationship between potential and kinetic energy is the subject of this blog post. Potential Energy is defined as the stored energy that exists in an object due to position.

Kinetic Energy, on the other hand, is a type of energy that arises from motion. The two are connected by what’s called conservation of mechanical energy which states that if no external forces act upon it then the total mechanical energy will remain constant over time.

The next section will go more in depth about how these energies work together and show you some examples.

## How are potential and kinetic energy used in everyday life?

Everyday life is full of examples of how potential and kinetic energy are used. For instance, the process of boiling water for tea involves both forces. When you put a pot on the stove, it begins to heat up because it has stored potential energy from being heated in an oven before.

At the same time, as water boils its molecules move faster and faster until they break through their bonds with other molecules and turn into steam that will be released into your home – this represents kinetic energy at work!

## Why do particles have both kinetic and potential energy?

Kinematics is the study of motion and how it relates to objects in space. Kinetic energy is defined as the energy that an object possesses because of its motion, while potential energy refers to the stored or converted form of kinetic energy when a body has been moved from one point in space to another.

Generally speaking, particles have both kinetic and potential energies due to their natural movement in three-dimensional space.

## What best compares kinetic and potential energy?

These two types of energy are often confused with one another. Kinetic energy is the movement and potential energy is the stored up power in an object, such as a rubber band or weight on a scale.

The greatest example of kinetic and potential energies would be when someone jumps off a diving board into water below.

When they jump from the top, they have all their kinetic energy because they’re moving down to the ground at high speeds; but once they hit the water, that kinetic energy becomes potential and bubbles out in waves around them.

## What factors affect kinetic energy?

Many factors affect kinetic energy. Kinetic energy is the measure of an object’s movement and it can be increased or decreased by changing either its mass, velocity, or both.

For example, if you were to roll a ball up a flight of stairs the higher you go the more potential energy will be converted into kinetic because there is less gravitational force working against it.

On the other hand if we threw a ball downward we would convert all of our potential energy into kinetic because gravity always works in one direction pulling objects down towards earth.