Potential energy difference related qs

In summary, the process of bringing a test charge from one position to another in an electric field of another charge involves an external force being applied, which is nearly equal to the electric force between the charges. This is possible because the extra force is only needed at the beginning and end of the process and can be reduced in between. If the field is conservative, the total work done will equal the change in the charge's potential energy, regardless of the size or duration of the additional forces applied.
  • #1
tecnics
6
0
in bringing a test charge (+q ) from a postion to another in an electric field of another charge +Q an external force , F is applied which is just as same as the electric force, F(electric)

how is this possible?

doesnt an unbalanced force be required to...bring about this process?

note: there is repulsive force between the charges...

can anyone explain to me about what is happening here??
 
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  • #2
I think...

The force is applied is slightly greater than the electric force but not exactly equal.

But there is not much difference between this two.

so we take applied force equal to electric force.
 
  • #3
Work was done to bring about the situation you describe - in the same way that work is down when lifting something against gravity. If you are worried about the 'extra' force, needed to get things going (moving) then, if the field is conservative, this extra force is only there at the start and then F can be reduced near the end of the ride. In a practical situation there would be a small amount of Kinetic Energy in whatever it is that's carrying the charge but it all goes into the Potential Energy at the end.
The simple scenario would be to consider the process being carried out infinitely slowly but the speed doesn't actually matter.
 
  • #4
If there are no other forces besides the electric force and the force that you exert in order to move or hold the charge:

1. Imagine holding the charge stationary at its original position. The net force is zero.

2. Start moving the charge towards its new position. You briefly exert a force that is slightly larger than before, so the net force is nonzero and the charge accelerates.

3. After the charge has started to move, you reduce your force to its original value, so the net force is zero again, and the charge continues to move with constant velocity towards its final position. If the electric force changes along the way, you change your force also, to keep the net force equal to zero.

4. When the charge is close to its final position, you briefly exert a bit of "extra" force in the opposite direction to bring the charge to rest at its final position.

The "extra" forces that you exert in steps 2 and 4 do work that is opposite in sign (positive work in step 2 and negative work in step 4) so they cancel out. The total work that you do during the entire process is equal in magnitude and opposite in sign, to the work done by the electric field.
 
  • #5
jtbell said:
2. Start moving the charge towards its new position. You briefly exert a force that is slightly larger than before, so the net force is nonzero and the charge accelerates.

The point about a conservative field, however, is that you can apply any forces you like on the way from A to B and achieve the displacement in any time you choose. The total work done will always be the same. More force at one time will always be made up for with less force at another time (or even some forces in the 'wrong directions'). All that's required is that the charge is stationary at each end of the process.
 
  • #6
sophiecentaur said:
All that's required is that the charge is stationary at each end of the process.

Yes indeed! I was just simplifying the situation to (hopefully) make it easier to grasp. You can make my "extra" forces at the beginning and end as small as you like, and as brief as you like, so long as they "match up" so the charge comes to rest at the end. The process will still work out, and the total work that you do will still equal the change in the charge's potential energy. It will merely take longer for the charge to make the trip.
 
  • #7
jtbell said:
Yes indeed! I was just simplifying the situation to (hopefully) make it easier to grasp. You can make my "extra" forces at the beginning and end as small as you like, and as brief as you like, so long as they "match up" so the charge comes to rest at the end. The process will still work out, and the total work that you do will still equal the change in the charge's potential energy. It will merely take longer for the charge to make the trip.

My additional point was that they can be as Large as you like, too and you still get the same answer.
 

1. What is potential energy?

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

2. What is the formula for calculating potential energy?

The formula for potential energy is PE = mgh, where PE represents potential energy, m is the mass of the object, g is the acceleration due to gravity, and h is the height of the object.

3. How is potential energy related to kinetic energy?

Potential energy and kinetic energy are both forms of energy that an object can possess. 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. The two are related because potential energy can be converted into kinetic energy and vice versa.

4. What factors affect potential energy?

The factors that affect potential energy include the mass of the object, the acceleration due to gravity, and the height of the object. The greater the mass, acceleration, or height, the greater the potential energy.

5. How can potential energy be used in everyday life?

Potential energy is used in a variety of ways in everyday life. Some examples include hydroelectric power plants that use the potential energy of water to generate electricity, roller coasters that use the potential energy of the initial climb to power the rest of the ride, and a stretched rubber band that has potential energy and can be released to do work.

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