Is the Aharonov-Bohm Effect Achievable in Practice?

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Discussion Overview

The discussion centers on the feasibility of achieving the Aharonov-Bohm effect in practice, particularly focusing on the theoretical possibility of having a magnetic field that is non-zero only within a specific range. Participants explore the implications of such a field on the effect's significance and its experimental realizability.

Discussion Character

  • Exploratory
  • Debate/contested
  • Technical explanation

Main Points Raised

  • Some participants question whether it is theoretically possible to have a magnetic field that is exactly zero outside a certain region, suggesting that this condition is crucial for the Aharonov-Bohm effect.
  • Others argue that while achieving an exactly zero magnetic field is impractical, it is possible to create conditions where the magnetic field is negligible enough to not affect the outcome of the experiment.
  • A participant mentions that the Aharonov-Bohm effect can be observed in superconducting rings, where magnetic field exclusion is significant.
  • Concerns are raised about the implications of using idealized models, such as infinitely long solenoids or specific charge and current distributions, and whether these models can be reconciled with practical experiments.
  • Some participants emphasize the importance of the magnetic vector potential in influencing the phase of electrons, suggesting that the effect's significance lies in this aspect rather than the magnetic field itself.
  • There is a contention regarding the relevance of ideal conditions in understanding the Aharonov-Bohm effect, with some asserting that idealizations should not detract from the learning process.

Areas of Agreement / Disagreement

Participants express differing views on the theoretical and practical aspects of achieving the Aharonov-Bohm effect, with no consensus reached on the feasibility of having a magnetic field that is exactly zero outside a certain region. The discussion remains unresolved regarding the implications of idealized conditions on the effect's significance.

Contextual Notes

Participants highlight the limitations of idealized models and the challenges of achieving conditions that are theoretically perfect in practice. The discussion reflects a range of assumptions about the nature of magnetic fields and their effects on quantum phenomena.

nonequilibrium
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So the Aharonov-Bohm effect relies on a magnetic field that is only non-zero within a given range. However, is it possible, even in principle (i.e. theoretically), to have such a magnetic field?
 
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It is possible to get a very good approximation.
The effect does not require zero field strength anywhere - the interesting thing is just that it works with zero field strength, too.
 
The effect does not require zero field strength anywhere - the interesting thing is just that it works with zero field strength, too.

But the surprising element of the effect relies on the field being (exactly) zero outside the given region; if the field is not exactly zero (again: not even theoretically [because obviously experimentally it will never be exactly zero]), the significance of the effect would be marginal, and the effect wouldn't be near as famous as it is today (at least I don't see any reason for this).
 
There are no frictionless planes, no massless pulleys, no stretchless ropes, and no regions with exactly zero magnetic field. You shouldn't let this get in the way of your understanding, because there are regions where the friction, mass, elasticity and exact zeroness of the field are unimportant.
 
Vanadium, if you'll look at my above posts, I emphasized as often as I could "even theoretically". Theoretically there are frictionless planes, etc. But are there theoretically (i.e. consistent with Maxwell's laws, or maybe even with QED if need be) magnetic fields which are only non-zero within a certain boundary?

If the answer is "no", then the Aharonov-Bohm effect seems to be nothing special.

EDIT: also, I wouldn't call this matter unimportant in the context of the Aharonov-Bohm effect; rather, it's the whole shabang.
 
mr. vodka said:
[...], I emphasized as often as I could "even theoretically".
Well, "theoretically" you could have an infinitely long ideal solenoid (of infinitesimal diameter)...
 
I don't like your first example, as it contains something infinitely big and hence e.g. infinite energy, but I think I do like your second example. I'm still not completely sold about it, as it contains a limiting procedure. But I think we can avoid that: do you think that specifying the following charge and current distribution will give a zero field outside of a torus?
Charge = 0
Current = along the circumference of the circles that make up the torus

I would think so... and that would answer my question. Thank you :)
 
mr. vodka said:
So the Aharonov-Bohm effect relies on a magnetic field that is only non-zero within a given range. However, is it possible, even in principle (i.e. theoretically), to have such a magnetic field?


Of course it is possible.

The AB effect is most easily seen in a magnetic field excluded environment in a superconducting ring. You can't get much greater magnetic field exclusion in a region than that.
I don't exactly understand the nature of your concern...
It is the Magnetic vector potential that affects the phase of electrons, and it is the strength of the vector potential that determines the phase change...

And the AB effect is very significant...in that it accounts for the magnetic quantum flux requirement in a superconductive ring.

...
 
Last edited:
It is not possible - even theoretically - to have a frictionless plane, a massless pulley, etc. Or an identically zero magnetic field over a region large enough to perform this experiment. Every ideal experiment is realized in some way where something is not ideal. That's not a reason not to learn from them.

In the case in question, B cannot be made identically zero. However, what one can do is make B too small to have a measurable impact on the outcome, so everything observable is driven by the strength of A. Surely that should be enough.
 

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