Why I doubt the generality of Gauss' law: A Gaussian sphere 1 light year across

In summary, the electric field at the other side of the sphere does not "update" until nearly 1 year later.
  • #36
DaleSpam said:
EDIT: Btw, perhaps I should ask. Do you understand that the integral and the differential forms of Gauss' law are equivalent?

I -accept- that they are.
 
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  • #37
kmarinas86 said:
You did not stick the context of the OP, and it has nothing to do with 1 ft.
I only mention 1 ft because I know that light travels at 1 ft/ns. The speed of light isn't such a nice number in cm.

Do you really think it makes a difference? If so, what is so special about cm and years that EM somehow does things in units of cm and years? I.e. why do you think that the field will take exactly 1 year to update from a distance of 1 cm? If you don't think that it makes a difference then why object?
 
  • #38
kmarinas86 said:
I -accept- that they are.
Then I don't understand your whole question. If it is EM then by definition it satisfies Gauss' law, and it doesn't matter if you express it in the differential or in the integral form.
 
  • #39
kmarinas86 said:
If move the charge out of that sphere and then stop it 1 centimeter outside of it

How fast were you planning on moving that charge out of the sphere?
 
  • #40
pervect said:
I think part of the machinery that makes field lines work is that you can write a general two-form as the sum of two wedge products of one-forms in 4 dimensions, and this is peculiair to 4-d. These two wedge products of one forms have a geometric interpretation as electric field lines and magnetic field lines, and their sum gives you the general rank two tensor. Unfortunately I'm going from memory here - I think this was mentioned briefly in MTW, but it's a huge book to search to find the section to refresh my memory about.

It's in the chapter on differential forms (chapter 4). But yes, there you have "tubes" (suitably abstracted) of flux, but the number of tubes pierced by a surface must give you the charge enclosed in the hypersurface (with some constants).
 
  • #41
DaleSpam said:
Do you really think it makes a difference?

Yes. 1 year minus 1 second.

DaleSpam said:
If so, what is so special about cm and years that EM somehow does things in units of cm and years?

Nothing.

DaleSpam said:
I.e. why do you think that the field will take exactly 1 year to update from a distance of 1 cm?

Actually I never said that.

DaleSpam said:
If you don't think that it makes a difference then why object?

You asked me, "Why would the field 1 ft away from the charge continue to change for 1 year after the charge has stopped moving?"

1 foot and 1 year taken together bears no relationship to the speed of light. Instead, it has a physically irrelevant speed of 9.65873546*10^-9 m/s, which has absolutely nothing to do with what is being discussed here.

When you said, "No. It does not continue to change at all. If the charge is made stationary at, say 1 ft away from some location then the field at that location will stop changing 1 ns after the charge becomes stationary." it was clear to me that:

1) This wasn't a question, so I didn't have to answer it. That's why I didn't even mention 1 ft in my reply.
2) By saying that the field "does not continue to change at all" in conjunction with the claim that "the field at that location will stop changing 1 ns after the charge becomes stationary", I presume that by "does not continue to change at all" that you meant "does not continue to change at all after 1 ns was passed". This was a poor analogy to what I was saying. So I said:

kmarinas86 said:
I didn't say it would change forever. I said, "Then, by definition the field near the charge, if made stationary after displacement, continues for 1 year to change..." This, means that for 1 year it continues to change.

And the last part, "...to reflect that the charge had been moved outside the sphere 1 year before." is about what happens 1 year later.

In other words, the field (on the sphere) continues to change for 1 year of synchronized time. Then the changes (on the sphere) cease as the new stationary field by the charge is "finished" on the sphere.
 
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  • #42
Khashishi said:
How fast were you planning on moving that charge out of the sphere?

Arbitrarily slow. In the context of the OP, just enough to move it 2 cm within a time span far less than 1 year.
 
  • #43
pervect said:
It's not clear what sort of proposal you're thinking about, but if it's along some von-Flanderen ideas, it's well known that delay in the force will yield a non-conservation of angular momentum.

A delay in the force will yield a non-conservation of angular momentum if you neglect field momentum. A member of this forum did mention this:

codelieb said:
Feynman addresses this (so-called) paradox in the final paragraph of FLP Vol. II Chapter 27, Field Energy and Field Momentum:

"Finally, another example is the situation with the magnet and the charge,
shown in Fig. 27-6. We were unhappy to find that energy was flowing around
in circles, but now, since we know that energy flow and momentum are proportional,
we know also that there is momentum circulating in the space. But
a circulating momentum means that there is angular momentum. So there is
angular momentum in the field. Do you remember the paradox we described in
Section 17-4 about a solenoid and some charges mounted on a disc? It seemed
that when the current turned off, the whole disc should start to turn. The puzzle
was: Where did the angular momentum come from? The answer is that if you
have a magnetic field and some charges, there will be some angular momentum
in the field. It must have been put there when the field was built up. When
the field is turned off, the angular momentum is given back. So the disc in the
paradox would start rotating. This mystic circulating flow of energy, which at
first seemed so ridiculous, is absolutely necessary. There is really a momentum
flow. It is needed to maintain the conservation of angular momentum in the
whole world."

This, however, is merely a qualitative description; sufficient quantitative (mathematical) information about the energy and momentum of the electromagnetic field is given in this chapter that a Caltech sophomore in his second year of the Feynman Lectures course would be expected to be able to find the final angular frequency of the disc as a function of the various parameters it depends on.

Mike Gottlieb
Editor, The Feynman Lectures on Physics, Definitive Edition
---
Physics Department
California Institute of Technology

I don't see the connection between that and the ideas of the not-so-well known "T. Von Flandern".
 
  • #44
pervect said:
I think part of the machinery that makes field lines work is that you can write a general two-form as the sum of two wedge products of one-forms in 4 dimensions, and this is peculiair to 4-d.

This has nothing to do with it. Field lines work because the source-free Maxwell equations imply that the 2-form F is harmonic.

Harmonic forms (in any dimension) have the distinction that they capture purely topological information. If you integrate a harmonic n-form over a closed n-surface, the result is either zero or non-zero, depending on whether the n-surface encloses some topological feature (for example, a 1-surface on a cylinder might wrap around the cylinder...or a 2-surface in R^3 might enclose a charge). Any n-surface that encloses the same set of topological features must give you the same result.

You can think of this as a higher-dimensional analogue of contour integration. In fact, all analytic functions on the complex plane satisfy Laplace's equation, which is why contour integration works.
 
  • #45
kmarinas86 said:
1 foot and 1 year taken together bears no relationship to the speed of light. Instead, it has a physically irrelevant speed of 9.65873546*10^-9 m/s, which has absolutely nothing to do with what is being discussed here.
Similarly with 1 cm and 1 year, so I don't get why you object to replacing the 1 cm with 1 ft. That is all I was doing, because 1 ft is a more convenient small distance than 1 cm.

kmarinas86 said:
I said, "Then, by definition the field near the charge, if made stationary after displacement, continues for 1 year to change..." ... In other words, the field (on the sphere) continues to change for 1 year
Sorry about my confusion. I don't know how I could have possibly been so obviously mistaken as to think that "near" referred to the field 1 cm or 1 ft away from the charge when it so obviously should refer to the field 1 ly away :rolleyes:

Just to be clear at each point in space the field changes from [itex]t_i+d_i/c[/itex] to [itex]t_f+d_f/c[/itex] where [itex]t_i[/itex] is the time that the charge starts moving, [itex]t_f[/itex] is the time that the charge stops moving, [itex]d_i[/itex] is the initial distance to the charge, and [itex]d_f[/itex] is the final distance to the charge. The field at that point does not change outside of those times.
 
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  • #46
Ben Niehoff said:
This has nothing to do with it. Field lines work because the source-free Maxwell equations imply that the 2-form F is harmonic.

Harmonic forms (in any dimension) have the distinction that they capture purely topological information. ...

I'd love to read a fuller explanation if you know of any papers or references on the topic of harmonic forms.
 
  • #47
Ok, I have constructed a simple equivalent problem to the original post which has an exact solution and can therefore be tested.

Arrange a dipole oscillating at any frequency you choose at the origin and oriented along the z axis. The complete fields of this dipole including the radiation fields are known exactly.

For the Gaussian surface chose the xy plane enclosed by a hemisphere at infinity. The fields on the hemisphere are radiation fields only and tend to zero.

Therefore you only need to integrate the z component of the dipole electric field over the xy plane.

If Gauss's law holds, this space integral evaluated along time will be +e when the positive charge is above the xy plane and -e when the negative charge pops up. Moreover, the integral should be exactly zero when the dipole charges cross at the origin despite the fact that significant non-zero radiation fields exist on the plane.

Anyone doubting the generality of Gauss's law can prove it using this integral.

I recommend writing the fields in spherical coordinates then performing the integration in cylindrical coordinates over r, theta.
 
  • #48
I don't get what exactly your claim is, please tell me which of the following:

- Gauss theorem is mathematically wrong, i.e. all mathematicians after Gauss failed in proving that theorem.

- Gauss Theorem is true, but is not applicable to physic, i.e. Maxwell's equations are wrong (or not general).
In this case you obviously can't prove this resolving Maxwell's equations for a oscillating dipole.

As the first of this option isn't actually acceptable to me, I don't see what utility could have to do math in the example you proposed.

If you claim is though that gauss theorem is wrong, I'd suggest to look for an error in the proof (I really can't find it).

Ilm
 
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  • #49
Ben Niehoff said:
This has nothing to do with it. Field lines work because the source-free Maxwell equations imply that the 2-form F is harmonic.

Harmonic forms (in any dimension) have the distinction that they capture purely topological information. If you integrate a harmonic n-form over a closed n-surface, the result is either zero or non-zero, depending on whether the n-surface encloses some topological feature (for example, a 1-surface on a cylinder might wrap around the cylinder...or a 2-surface in R^3 might enclose a charge). Any n-surface that encloses the same set of topological features must give you the same result.

You can think of this as a higher-dimensional analogue of contour integration. In fact, all analytic functions on the complex plane satisfy Laplace's equation, which is why contour integration works.

Just to clarify, by harmonic you mean: [tex](d\delta+\delta d)F=0[/tex] where d is the exterior derivative and delta is the co-dfifferential?

Is this true? It seems since dF=0 by definition, then we need to show: [tex]d\delta F=-d(*d*F)=4\pi(d**J)=0[/tex]

Is it true that [tex]dJ=0[/tex]? I can't think of a reason for this...

EDIT: Wait, is that just conservation of charge? It certainly isn't the usual way of expressing it...and I can't seem think think clearly enough at this late hour to figure this out...lol...
 
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  • #50
I said source-free Maxwell equations, which are

[tex]dF = d * F = 0[/tex]
 
  • #51
But the source free Maxwell equations can't have a charge inside your surface...? So how does that apply to Gauss's law in what we are talking about here? I guess I don't quite get your argument then.
 
  • #52
The source-free Maxwell equations apply to everywhere where the charge isn't. That is, ALL of space except for the one point where the charge is.

Or in other words, it so happens that J=0 except at one point.
 
  • #53
Certainly one would like Gauss's law to hold even if you are inside a continuous charge distribution though. How does that work then in that case?
 
  • #54
Right. So, with sources, we have

[tex]d * F = * J[/tex]
So now, merely integrate this over some 3-volume V:

[tex]\begin{align*} \int_V d * F &= \int_V * J \\ \int_{\partial V} * F &= \int_V * J \end{align*}[/tex]
which is Gauss' Law.

The reason I focused on the source-free equations, is because it is only when [itex]J = 0[/itex] that the result of integration doesn't care about the choice of surface. Obviously, if [itex]J \neq 0[/itex], then different surfaces might contain different amounts of charge, hence giving different results. Gauss' Law still holds, though.
 
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  • #55
I guess my question, what does F being harmonic have to do with field lines? It seems to me that Stokes theorem is sufficient in both (empty space and continuous charge) cases to justify the use of field lines.
 
  • #56
i completely agree with kmarinas86. the field SHOULD continue to change for 1 year[approx].so far,none of the members have posted a convincing reason why it shouldn't.after all,information does take time to travel,and nothing happens instantaneously.once the charge is taken out of the sphere,the 'data' from the other side of the sphere would take time[almost 1 year] to reach the side that was initially closer to the charge
 
  • #57
Matterwave said:
I guess my question, what does F being harmonic have to do with field lines? It seems to me that Stokes theorem is sufficient in both (empty space and continuous charge) cases to justify the use of field lines.

You're right. Harmonic forms are special for other reasons that don't necessarily apply here.
 
  • #58
ARAVIND113122 said:
i completely agree with kmarinas86. the field SHOULD continue to change for 1 year[approx].so far,none of the members have posted a convincing reason why it shouldn't.after all,information does take time to travel,and nothing happens instantaneously.once the charge is taken out of the sphere,the 'data' from the other side of the sphere would take time[almost 1 year] to reach the side that was initially closer to the charge
The Lienard Wiechert potential is the convincing reason. The LW potential depends only on the motion of the charge at the retarded time. So the field at the near side updates with ~1 ns delay and the field at the far side updates with ~1 year delay. The field does not change outside of the times as indicated above.

If you are not willing to accept standard solutions like the LW potential, then there is little that can or should be done to convince you.
 
<h2>1. Why is Gauss' law doubted?</h2><p>Gauss' law is doubted because it is based on the assumption that the electric field is radial and uniform at all points on a Gaussian sphere. This may not always be the case in real-world scenarios.</p><h2>2. What is a Gaussian sphere?</h2><p>A Gaussian sphere is an imaginary spherical surface used in Gauss' law to calculate the electric field at a point due to a charge distribution.</p><h2>3. Why is the Gaussian sphere chosen to be 1 light year across?</h2><p>The size of the Gaussian sphere is chosen to be 1 light year across in order to encompass a large enough volume to accurately represent the charge distribution in question.</p><h2>4. How does the size of the Gaussian sphere affect the accuracy of Gauss' law?</h2><p>The larger the Gaussian sphere, the more accurate the results of Gauss' law will be. However, if the sphere is too large, it may not accurately represent the local charge distribution and lead to errors in calculations.</p><h2>5. Are there any limitations to Gauss' law?</h2><p>Yes, there are limitations to Gauss' law. It assumes that the electric field is radial and uniform, and does not take into account factors such as non-uniform charge distributions or changing electric fields over time. It is also only applicable in electrostatic scenarios, and does not apply to situations with moving charges or changing magnetic fields.</p>

1. Why is Gauss' law doubted?

Gauss' law is doubted because it is based on the assumption that the electric field is radial and uniform at all points on a Gaussian sphere. This may not always be the case in real-world scenarios.

2. What is a Gaussian sphere?

A Gaussian sphere is an imaginary spherical surface used in Gauss' law to calculate the electric field at a point due to a charge distribution.

3. Why is the Gaussian sphere chosen to be 1 light year across?

The size of the Gaussian sphere is chosen to be 1 light year across in order to encompass a large enough volume to accurately represent the charge distribution in question.

4. How does the size of the Gaussian sphere affect the accuracy of Gauss' law?

The larger the Gaussian sphere, the more accurate the results of Gauss' law will be. However, if the sphere is too large, it may not accurately represent the local charge distribution and lead to errors in calculations.

5. Are there any limitations to Gauss' law?

Yes, there are limitations to Gauss' law. It assumes that the electric field is radial and uniform, and does not take into account factors such as non-uniform charge distributions or changing electric fields over time. It is also only applicable in electrostatic scenarios, and does not apply to situations with moving charges or changing magnetic fields.

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