Potential Energy and the Conservation of Energy

In summary, potential energy is a type of stored energy that can be defined by a potential energy function and is necessary for conservation of energy. It arises in the presence of conservative forces and is equal to the sum of kinetic energy and potential energy. However, conservation of mechanical energy requires that only conservative forces be present.
  • #1
scotty_le_b
19
0
Would I be right in saying the following:
Potential energy arises from the conservation of energy. To lift a mass you must exert a force counteracting the force of gravity. As it moved and a force was exerted work was done on it. As it is not moving it has no kinetic energy. Due to the conservation of energy the energy cannot be destroyed so there must be a stored type of energy...Potential energy.
 
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  • #2
Sounds good to me.
 
  • #3
scotty_le_b said:
As it moved and a force was exerted work was done on it. As it is not moving it has no kinetic energy.

This seems rather confused. Either it is moving, or it isn't. It can't be moving and not moving at the same time.

I would say potential energy has nothing to do with conservation of energy. If you have a situation where the amount of work done on something when it moves between two positions A and B does not depend on the exact path or on the speed that it moves, but only on the positions of A and B, then you can define a "potential energy function" that let's you calculate the amount of work done easily.

Gravity is a good example. If you are working close to the sirface of the Earth you can assume gravity is a constant force, and define its potential energy as mgh. Or if you want to consider the inverse square law, you can use a potential energy function that is proportional to 1/r where r is the distance between two objects. (Note, 1/r was not a typo for 1/r2)

You can also define potential energy for other types of force. For example, guess why the voltage between two points in an electrical circuit is sometimes called the "potential difference"...
 
  • #4
What I meant by that it was moved up to say a shelf then on the shelf it was not moving. Sorry
 
  • #5
AlephZero said:
This seems rather confused. Either it is moving, or it isn't. It can't be moving and not moving at the same time.

I would say potential energy has nothing to do with conservation of energy. If you have a situation where the amount of work done on something when it moves between two positions A and B does not depend on the exact path or on the speed that it moves, but only on the positions of A and B, then you can define a "potential energy function" that let's you calculate the amount of work done easily.

Gravity is a good example. If you are working close to the sirface of the Earth you can assume gravity is a constant force, and define its potential energy as mgh. Or if you want to consider the inverse square law, you can use a potential energy function that is proportional to 1/r where r is the distance between two objects. (Note, 1/r was not a typo for 1/r2)

You can also define potential energy for other types of force. For example, guess why the voltage between two points in an electrical circuit is sometimes called the "potential difference"...

How can you say potential energy has nothing to do with conservation of energy? IMO, potential energy is NECESSARY for conservation of energy. The potential energy + kinetic energy (in your gravitational situation, classically) is the total energy. Sometimes the potential is zero, sometime kinetic is zero, and sometimes neither is zero (and we can actually arbitrarily define the potential to be zero at any point).

Without potential energy, I don't think conservation of energy would not be satisfied.
 
  • #6
khemist said:
How can you say potential energy has nothing to do with conservation of energy? IMO, potential energy is NECESSARY for conservation of energy. The potential energy + kinetic energy (in your gravitational situation, classically) is the total energy. Sometimes the potential is zero, sometime kinetic is zero, and sometimes neither is zero (and we can actually arbitrarily define the potential to be zero at any point).

Without potential energy, I don't think conservation of energy would not be satisfied.

Amusingly, your last sentence is a double negative. Anyway...

Potential energy only arises in the presence of conservative forces. Total energy of a system is always conserved, even when the forces present are not conservative. Perhaps you are confusing conservation of energy with conservation of mechanical energy (which requires that only conservative forces be present)?

Mechanical energy = kinetic energy + potential energy.

EDIT: AlephZero's second paragraph basically defines what a conservative force is.
 

1. What is potential energy?

Potential energy is the energy that an object possesses due to its position or condition. It is stored energy that has the potential to do work in the future.

2. How is potential energy different from kinetic energy?

Potential energy is the energy an object has due to its position, while kinetic energy is the energy an object has due to its motion. They are two different forms of energy that can be converted into each other.

3. How is potential energy related to the conservation of energy?

The conservation of energy states that energy cannot be created or destroyed, only transferred or converted. This means that potential energy can be converted into other forms of energy, such as kinetic energy, but the total amount of energy in a system remains constant.

4. What are some examples of potential energy?

Some examples of potential energy include: a stretched rubber band, a ball sitting at the top of a hill, a compressed spring, and a book on a high shelf.

5. How can potential energy be calculated?

The formula for calculating potential energy is PE = mgh, where m is the mass of the object, g is the acceleration due to gravity, and h is the height of the object. This formula can be used for objects near the Earth's surface, where the gravitational force is constant.

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