It’s the same with a roller coaster that halts at the highest point of the rails. You should also know that gravitational potential energy and elastic energy potential energy can be differentiated even further based on mechanical energy.įor instance, a car parked at the top of a hill is an example of mechanical gravitational potential energy since the automobile has the potential to come down the hill. While it already has more potential energy, the further you stretch it, the higher the elastic potential energy will be. A classic example is a stretched rubber band. The more the object is stretched or compressed, the more elastic potential energy it’ll have. Įlastic potential energy is stored in objects that can either be stretched or compressed. There are three main types of potential energy: elastic potential energy, gravitational potential energy, and chemical potential energy. However, as soon as the book hits the floor, this energy of motion will again convert to potential energy. But when you accidentally knock it off the table, this potential energy will turn into kinetic energy while the book falls since it’s in motion. When the book is at rest, it has potential energy. Let’s use another example: Imagine there is a book on a table. In other words, potential energy transforms into kinetic energy, and kinetic energy converts into potential energy, and then back again. The primary relationship between the two is their ability to transform into each other. You now know that potential energy is position relative, and kinetic energy is motion relative. What Is the Relationship Between Potential and Kinetic Energy? The stationary hammer then has stored energy in the form of potential energy.Īs this example demonstrates, energy is neither destroyed nor lost during the whole process – it’s only altered from one form to another, proving the law of conservation of energy. (It’s the falling hammer that has kinetic energy.) Third, as soon as the hammer hits the table, the energy changes. Second, when you hit the hammer on the table, the stored potential energy is converted to kinetic energy as the hammer is falling. There are three interesting things you should note here.įirst, the raised hammer has more potential energy since it has the potential to go higher or lower. But as you drop the hammer downwards to bang on a table’s surface, it’ll have kinetic energy. When you raise the hammer higher, it’ll have potential energy. Let’s explain P.E and K.E with the help of an example. Kinetic energy can be transferred from one moving object to another (vibration and rotation) and is dependent on an object’s spee d or v elocity and mass. Potential energy isn’t transferrable and it depends on the height or distance and mass of the object. For instance, the kinetic energy of the object will be higher if the object is placed at a greater height. Contrary to potential energy, the kinetic energy of an object is relative to other stationary and moving objects present in its immediate environment. On the other hand, kinetic energy is the energy of an object or a system’s particles in motion. However, it isn’t affected by the environment outside of the object or system, such as air or height. Potential energy is the stored energy in any object or system by virtue of its position or arrangement of parts. Potential energy can be converted to kinetic energy and vice versa. Potential and kinetic energy are two forms of energy that can be converted into each other. You need energy to do any work, which is why the ability to do any work is energy. What Is Potential and Kinetic Energy and What Are Their Differences? Read on as we discuss these two energy forms in greater detail and explore the relationship between them. Whenever you use or store energy, you deal with potential or kinetic energy. It can neither be created nor destroyed, but it can be altered.
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