Electrostatic Potential Concept

In summary: The force of gravity is constantly pulling it down, but if you hold the weight off the ground for a long time, the spring will eventually give up and the weight will be pulled down by the gravity.I do not know about v, that's why I was asking,but I surely know that the longer you expose anything to a force the greater is the KE acquired. Think about...a weight on a spring. The force of gravity is constantly pulling it down, but if you hold the weight off the ground for a long time, the spring will eventually give up and the weight will be pulled down by the gravity.
  • #1
thebiggerbang
75
0
My textbook says that Electrostatic potential is the work done on a unit charge to bring it from infinity to a point from a given charge without acceleration, against the electric field presend due to the given charge.

So, as it says that there will be no acceleration, does it imply that there will be no change in the velocity of the charge that we are moving? And thus, does this imply that there is no change in the kinetic energy of the charge?
 
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  • #2
So, as it says that there will be no acceleration, does it imply that there will be no change in the velocity of the charge that we are moving? And thus, does this imply that there is no change in the kinetic energy of the charge?

Yes that's correct.

Another way to put this is to say that for its entire journey from infinity to its location, the charge is in equlibrium or passes through a series of equilibrium states.

go well
 
  • #3
Also, when a charge is accelerated, it emits electromagnetic radiation. It implies that no work is wasted in generating these propagating modes of the electromagnetic field.
 
  • #4
BTW, this definition assumes that the electric potential at infinity is taken as zero (electric potential, like potential energy is determined up to an additive constant). This is possibly only for fields that decay fast enough at infinity, like, for example, the field of a point charge (that decays inversely proportional to the square of the distance). However, the field from a uniformly charged infinite line decays inversely proportional to the distance from the line and the potential is logarithmically divergent. The field of a uniform electric field gives a linearly divergent potential. Although all fields generated by real bodies decay sufficiently fast, sometimes it makes sense to take into account such idealized field sources for which your definition is not directly applicablel
 
  • #5
thebiggerbang said:
And thus, does this imply that there is no change in the kinetic energy of the charge?

Studiot said:
Yes that's correct.

Is the absolute value of kynetic energy not relevant?, any speed will do, as long as it remains constant?

In many textbooks I read slowly
What is slowly?
 
  • #6
This is because you are dealing with electrostatics. If the charge is moving rapidly, you are dealing with electrodynamics and magnetic fields. I don't really know what exactly is slow enough to be described by electrostatic theorems, though.
 
  • #7
rbnvrw said:
This is because you are dealing with electrostatics. ... I don't really know what exactly is slow enough to be described by electrostatic theorems, though.

My point is that (KE), velocity cannot be left vague.
because if v is half, then time t is double.
Then also total work done on charge (PE) is double, or more

So what is the correct Electrostatic Potential Energy?
 
  • #8
If you travel from infinity with any finite speed, the time is infinite. If you half the speed, time remains the same, namely, infinite.
 
  • #9
Dickfore said:
If you travel from infinity with any finite speed, the time is infinite. If you half the speed, time remains the same, namely, infinite.

so, what is E-PE?
it seems we cannot calculate it!


b)And what if you don't start from infinity?
 
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  • #10
formal said:
And what if you don't start from infinity?

But, look at the definition you quoted. It says taken from infinity.
 
  • #11
thebiggerbang said:
1) Electrostatic potential is the work done on a unit charge to bring it from infinity to a point from a given charge without acceleration, against the electric field presend due to the given charge.
Studiot said:
2)Yes that's correct.

Dickfore said:
But, look at the definition you quoted.
It says taken from infinity.

That's my quote 1 and 2:
how do we calculate E-PE from infinity to a point if time is infinite?

b) if we do not start from infinity, the absolute value of velocity is not relevant?
again, what is the threshold?
 
  • #12
formal said:
My point is that (KE), velocity cannot be left vague.
because if v is half, then time t is double.
Then also total work done on charge (PE) is double, or more

So what is the correct Electrostatic Potential Energy?

You are doing a mistake here, the work done on the particle doesn't depend on its velocity neither on the time it takes, because the force that does this work doesn't depend on velocity(the electric field is only due to the given charge which is considered stationary, while we consider the field from the moving unit charge negligible) neither on time (it is constant with time)
 
  • #13
formal said:
That's my quote 1 and 2:
how do we calculate E-PE

what does this have to do with anything?
 
  • #14
Delta² said:
the work done on the particle doesn't depend on its velocity neither on the time it takes, because the force that does this work doesn't depend on velocity)

I do not know about v, that's why I was asking,
but I surely know that the longer you expose anything to a force the greater is the KE acquired. Think about gravity!
 
  • #15
Dickfore said:
what does this have to do with anything?

If one says that PE is calculated bringing a test charge from infinity to anywhere and
the time required to do this is infinite, then he is saying simply we cannot calculate it, at any speed.

Am I wrong?
 
  • #16
formal said:
If one says that PE is calculated bringing a test charge from infinity to anywhere and
the time required to do this is infinite, then he is saying simply we cannot calculate it.

Am I wrong?

Yes. The work done by a conservative force is equal to the difference between the initial potential energy and the final potential energy:

[tex]
W_{\mathrm{cons}} = (E_{p})_{i} - (E_{p})_{f}
[/tex]

The work-energy theroem tells us that the total work done on an object is equal to the change in kinetic energy. In our case, since there is no acceleration, the velocity of the object remains the same, therefore the change in kinetic energy is zero, regardless of the speed of the object.

Furthermore, there are two forces acting on the object at any time. The electrostatic force (no Lorentz force since the speed of the object is infinitely small) and the external force that counters it. Therefore, the work-energy theorem gives:

[tex]
W_{\mathrm{ext}} + W_{\mathrm{cons}} = 0
[/tex]

Substituting for the work done by the conservative (electrostatic) force:

[tex]
W_{\mathrm{ext}} + \left((E_{p})_{i} - (E_{p})_{f}\right) = 0
[/tex]

Solving for the final potential energy:
[tex]
(E_{p})_{f} = (E_{p})_{i} + W_{\mathrm{ext}}
[/tex]

Now, we choose the normalization that [itex](E_{p})_{i} = (E_{p})_{\infty} = 0[/itex]. Then:
[tex]
(E_{p})_{f} = W_{\mathrm{ext}}
[/tex]

This is the mathematical formulation of the sentence stated in the OP.
 
  • #17
Is the absolute value of kynetic energy not relevant?, any speed will do, as long as it remains constant?

In many textbooks I read slowly
What is slowly?

Potential energy in any force system is independent of time and dependant solely on position.

That includes gravity.

We are discussing electric potential enrgy here.

The definition is specifically worded to run from infinity to the position because we cannot calculate the work of separating charges.

The calculation is easy and shown on post 40 of this thread

https://www.physicsforums.com/showthread.php?t=489731&highlight=potential

Your book says 'slowly' instead of 'equilibrium' or 'without acceleration' I expect. They are all equivalent statements.

The represent the desired condition that as the charge is brought in from infinity none of the work done against the electric force is converted to kinetic energy - it is all stored as electric potential energy.
This condition gives validity to the calculation described above.
 
  • #18
Dickfore said:
Yes.
This is the mathematical formulation of the sentence stated in the OP.

This is the maths formulation alright, and so I suppose it applies also to gravitation.
and I suppose it applies also in the case we do not start from infinity. (point b)


Imagine we have in vacuum 55200 esu,0.0000148 C ,positive charge ( 4x 10^14 at 1m).
An electron is at rest at r0= 10^7m/ (^9 cm.) (acc= 4 m/sec^2, 400cm/s^2).
If we move it to r = 6.4x 10^6m/ (^8cm) (acc= 9.8 m/s^2 ,980cm/s^2)
is work done on the charge the same if v changes? or is it useless and we need only Maths and
KE= Δ PE = 2.25 x 10^ 7 ?

That is to say the same KE an electron would get anyway in a free fall from r0 to r?
 
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  • #19
Studiot said:
Potential energy in any force system is independent of time


The calculation is easy and shown on post 40 of this thread

https://www.physicsforums.com/showthread.php?t=489731&highlight=potential

.

thank you for the link.
but the point is: is the definition given in the thread ,(you said it is correct), just a formal definition, meaning nothing in concrete.? or we can really use a test charge to measure Δ PE? or if we moved the two conductors of a capacitor?

In a cyclotron you have a set difference in E-PE, and every time a charge makes a jump from a Dee it gets the same amount of KE, independently of its velocity. Is that correct?
 
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  • #20
It is a formal definition. Potential energy is not operationally defined physical quantity, but a derived quantity.
 
  • #21
Dickfore said:
It is a formal definition.
Potential energy is not operationally defined physical quantity, but a derived quantity.

Thank you!
That is just what worried me.It really did not make much sense.
Now could you comment the two examples I made.
Is KE = 2.25x 10 ^7 J, final v= 1.8x 10^ 4 m/s, 18 Km/ sec if electron is at rest ? and much more if it is not?

And in a cyclotron why the increase in KE is the same at every passage even if speed is always different?
(P.S. should we say derived or derivative quantity?)
 
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  • #22
formal said:
Now could you comment the two examples I made.
Is KE = 2.25x 10 ^7/ 12? what is final v?

I can, but I won't.

formal said:
And in a synchrotron why is KE increase the same at every passage?

Because it always passes through the same potential difference between the duants.
 
  • #23
Dickfore said:
Because it always passes through the same potential difference between the duants.

That is why I asked for your comment on the other case.
In that case, in vacuum, an electron at rest gets less KE than an electron with v>0

Where is the difference?
 
  • #24
The difference is that moving an electron in the field of another point charge has nothing to do with the concept of a cyclotron.
 
  • #25
rbnvrw said:
This is because you are dealing with electrostatics. If the charge is moving rapidly, you are dealing with electrodynamics and magnetic fields. I don't really know what exactly is slow enough to be described by electrostatic theorems, though.

Thank you,
could you, please , explain how in the example at post #18, a rapidly moving charge's magnetic field would influence work done on it?
 
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  • #26
Going back to the OP:

This is the answer you are looking for...

Your book says 'slowly' instead of 'equilibrium' or 'without acceleration' I expect. They are all equivalent statements.

The represent the desired condition that as the charge is brought in from infinity none of the work done against the electric force is converted to kinetic energy - it is all stored as electric potential energy.
This condition gives validity to the calculation described above.

It's just an operational definition for convenience. The reference could have been chosen as -100 volts at infinity; very often in circuit problems Earth is assigned "zero" volts as the reference potential...
 
  • #27
Naty1 said:
It's just an operational definition for convenience. The reference could have been chosen as -100 volts at infinity; very often in circuit problems Earth is assigned "zero" volts as the reference potential...

Thank you,
the value at infinity is really irrelevant.
The point is the remainder of the definition:

is velocity important or not? if it is not , why bother?
if it is (as it figures), in what way is it relevant? is it a matter of MF?

please see previous post #25, and also 18,19
 
  • #28
is velocity important or not? if it is not , why bother?
if it is (as it figures), in what way is it relevant?

It is important NOT to change the velocity of the test particle much. That's because in the definition of potential energy you want to measure the work done against the static potential...NOT the work done to accelerate the particle related to kinetic energy...which must be kept small by comparison.

The work done in the static case is not dependent on the path taken.

If you move a test particle with a positive charge to closer proximity with a positvely charged particle it takes positive work...If of opposite charge, negative work...negative potential results...analogous to a (attractive) gravitational field where particles come closer together.
 
  • #29
Naty1 said:
1) It is important NOT to change the velocity of the test particle much.
2)The work done in the static case is not dependent on the path taken.

3)If of opposite charge, negative work...negative potential results...analogous to a (attractive) gravitational field where particles come closer together.

I think there is a misunderstanding, probably I haven't made it clear enough
I am not talking of (1) changing v or (2) changing path.
I am talking of absolute value of v, I stated it repeatedly

if a charge as v= 1, 10, 100 , does it make any difference?
is post #6 correct or false?

3) if a body in a gravitational field is at rest or has v = 1 or = 10 it matters! and how!
the greater is v, the greater is KE acquired (work done)
a charge in vacuum behaves differently from the same charge between two Dee's ? why?
 
  • #30
formal said:
but I surely know that the longer you expose anything to a force the greater is the KE acquired. Think about gravity!

No this is not true either. As long as the field is not time- varying the force that does the work will not be time-varying either so the work done by the force as defined by

[tex] \int_{C} F(r)dr[/tex] will not depend on time, it will depend only on the path C (and not how long it takes to travel through that path). Moreover since the electrostatic field is conservative it will depend only on the start and end points of the path C.
 
  • #31
There is a simple high school analogy.If you lift a mass M through a height h against a uniform gravitational field of field strength g then the gain of gravitational potential energy is Mgh.This change is dependant on M and g and the initial and final positions only and is independant of the method of lifting.If the mass is lifted infinitely slowly at an angle the change is Mgh.If it is fired vertically up at a billion metres per second then as the mass pases through a height h the gain of PE is again Mgh.Whatever method is used energy is conserved.
 
  • #32
OP here. I guess that the velocity of the charge that is being moved should tend to zero (vanishingly small) as if it is not so, then it implies that at some point of time the applied force was more than the force due to the electric field, there was no equilibrium.

Also, as we can't calculate the absolute energy of a system, we always consider the change in the energy of the system. For all practical purposes, we always use potential difference, and not the absolute potential. This difference will be always independent of the initial position of the charge (infinity on this case).

Mathematically, Potential difference to move a charge from A to B is given by

[itex]\Delta[/itex]P=P[itex]_{AB}[/itex]=P[itex]_{\infty B}[/itex]-P[itex]_{\infty A}[/itex]
=P[itex]_{B}[/itex]-P[itex]_{\infty}[/itex]-P[itex]_{A}[/itex]+P[itex]_{\infty}[/itex]
=P[itex]_{B}[/itex]-P[itex]_{A}[/itex]

I hope the formulation is correct
 
  • #33
OP here. I guess that the velocity of the charge that is being moved should tend to zero (vanishingly small) as if it is not so, then it implies that at some point of time the applied force was more than the force due to the electric field, there was no equilibrium.

Not exactly but almost.

Yes, as I said before, it is way of stating that none of the electric potential energy is converted to kinetic energy or that the electric force does not speed up the test charge.

However some other agent may be causing motion,independent of the electric effect.

Consider.

I float up to 10000ft in a balloon and stay there in equilibrium.

The balloon and contents have a certain PE due to the altitude..

If I now start the motor and propel the balloon horizontally at 1 mile/hr does the PE change if the altitude remains constant?

If I accelerate the balloon to 10 miles/hr does this change the PE?
 
  • #34
Studiot said:
1) it is way of stating that none of the electric potential energy is converted to kinetic energy or that the electric force does not speed up the test charge.

Consider.
I float up to 10000ft in a balloon and stay there in equilibrium.
The balloon and contents have a certain PE due to the altitude..

2) If I now start the motor and propel the balloon horizontally at 1 mile/hr does the PE change if the altitude remains constant?
3) If I accelerate the balloon to 10 miles/hr does this change the PE?

1) (EB) the explanation one reliable text gives for the motion being slow is:
"...this is the only case in which motion does not, of itself, cause work to be done elsewhere in the universe" ..." the vector curl E (del x E) must be zero"


2) , 3) If we move (a balloon or) a charge (horizontally or) in a normal direction to force E, PE , of course, does not change because work is not done against the force (as r0 -r = 0)(4*)

( 4*) text says work: W = q(o) * q/ 4π ε0 (1/ r0 -1/ r ) )

now if definition EB is correct, could you or someone help to interpret it?
in your previous post (#17) you interpret slowly as steadily, but if they wanted to mean steady they would just say steady.
If it is so, (and slow does not mean 'not accelerated') the absolute value of v is relevant:
OP pinpoints his previous 'without acceleration' to 'vanishingly small'. That is correct!That is what the definition is all about!

But the best way to explain it is to say what happens if v is greater, I suppose!
everyone has his own view: is post #6 correct? is post #24 correct? is post #20 correct?
Now consider this:

2,3) if you deflate your (balloon A) charge q(a) (if q(o)= 0.0000184 C)
will drop vertically and after 1 second it will gain
acc= v = 9.8 m/sec and KE = W(A)
if another (balloon B) charge q(b) is already (falling) moving alongside it at v 9.8 m/ sec it will change
its v from 9.8 to 19.6 m/ sec gaining KE W(B) > W(A) (= 4 W(A)) , while
in a cyclotron W(A)= W(B)=..W(C)...

In conclusion we have a (formal?, hypothetical?, meaningless?) definition of Electrostatic PE which states
that absolute value of v is relevant, whereas (as stated correctly in post #31)
it is not at all relevant in a gravitational field and
it is not at all relevant in an Electric field between two Dee's
 
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  • #35
I think the main reason the OP got confused is that he assumed,incorrectly, that there was an implication that the work done in moving from A to B is independant of the route taken and the method used to do that work.The key point is that it is the work done on (or by) the field that is independant of the route taken and the method used to do that work.
 
<H2>What is electrostatic potential?</H2><p>Electrostatic potential is the amount of electric potential energy per unit charge at a specific point in an electric field. It is a measure of the strength of the electric field at that point.</p><H2>How is electrostatic potential different from electric potential energy?</H2><p>Electric potential energy is the potential energy that a charged particle has due to its position in an electric field. Electrostatic potential, on the other hand, is the potential energy per unit charge at a specific point in the electric field.</p><H2>What is the unit of measurement for electrostatic potential?</H2><p>The unit of measurement for electrostatic potential is volts (V). It is equivalent to joules per coulomb (J/C).</p><H2>How is electrostatic potential calculated?</H2><p>Electrostatic potential is calculated using the formula V = kQ/r, where V is the electrostatic potential, k is the Coulomb's constant (9 x 10^9 Nm^2/C^2), Q is the charge of the particle, and r is the distance from the particle to the point where the potential is being measured.</p><H2>What is the significance of electrostatic potential in practical applications?</H2><p>Electrostatic potential is important in many practical applications, such as in the design of electronic devices, capacitors, and power systems. It is also used in medical imaging techniques, such as electrocardiograms and electroencephalograms, to measure the electrical activity of the heart and brain, respectively.</p>

What is electrostatic potential?

Electrostatic potential is the amount of electric potential energy per unit charge at a specific point in an electric field. It is a measure of the strength of the electric field at that point.

How is electrostatic potential different from electric potential energy?

Electric potential energy is the potential energy that a charged particle has due to its position in an electric field. Electrostatic potential, on the other hand, is the potential energy per unit charge at a specific point in the electric field.

What is the unit of measurement for electrostatic potential?

The unit of measurement for electrostatic potential is volts (V). It is equivalent to joules per coulomb (J/C).

How is electrostatic potential calculated?

Electrostatic potential is calculated using the formula V = kQ/r, where V is the electrostatic potential, k is the Coulomb's constant (9 x 10^9 Nm^2/C^2), Q is the charge of the particle, and r is the distance from the particle to the point where the potential is being measured.

What is the significance of electrostatic potential in practical applications?

Electrostatic potential is important in many practical applications, such as in the design of electronic devices, capacitors, and power systems. It is also used in medical imaging techniques, such as electrocardiograms and electroencephalograms, to measure the electrical activity of the heart and brain, respectively.

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