Will the electron affected by another electron via Coulomb's force affect this electron instantly?

Question

Coulomb's law is strict:

$F=k\dfrac{q_1*q_2}{r^2}$

that means that between two charges occurs force. I.e. occurs force on $q_1$ and on $q_2$.

If there are two electrons in vacuum with 300 00 000 meters distance between them, one electron feels force due to another, and another should instantly feel force due to first electron.

How does it possible? You probably will say something about energy propagation, speed of light, but it is not actually a light. Does it occurs instantly or not, and why?

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The general idea of this question is the fact that there are limits only for propagation of changable processes, as far as I know(like em waves). Coulomb's force is about two fixed charges in vacuum, there are no moving.

And the second idea -, even if, let's say, there is a need in time to one electron affect another - when it happens, first electron, according to law above, should instantly feel force.

Answer 1

Coulomb's Law is an electrostatic approximation (in which we assume the charges have always been where they are, and don't move) of a broader concept: the force a charge feels is the direct result of the electric and magnetic fields produced by other charges.

One of the most important facts in electromagnetism is the following statement: changes in the electromagnetic field travel at the speed of light. This makes sense, because light itself is a propagating change in the electromagnetic field.* This also means that the electromagnetic field produced by a charge encodes its history: for example, if it was moving in the past and is stationary now, then there is a region closer to the charge where the field is consistent with a stationary charge, a region further away from the charge in which the field is consistent with a moving charge, and a region of electromagnetic waves in between that were produced during the necessary acceleration; this boundary between the two regions expands outward at the speed of light.

So, to answer your question, you have to look at the history of the charges. Coulomb's Law is only valid if the charges' electric fields are pointing radially outward from their current position across all of space; this implies that both charges have been sitting in their current positions for all time (because if they weren't, then there would be a certain distance away from them where this wouldn't be true). If you were to quickly move both charges into their current positions at some point in time, it would take a nonzero amount of time for the resulting change in the electric field (from "no field" to "the electric field from a stationary charge") to propagate outward, and as such it would take some time for the two charges to feel force on each other.

So, long story short, if Coulomb's Law is assumed valid, then the charges have always been where they currently are, and the question of whether one feels the force of the other "instantly" is a moot point.

*Note that, while all changes in the electromagnetic field propagate at the speed of light, not all changes in the electromagnetic field correspond to the emission of electromagnetic radiation (i.e. "light"). In particular, only changes that propagate significantly to infinity are classified as such (in other words, only accelerating charges produce electromagnetic radiation, not charges moving at constant velocity).

Answer 2

First, you are asking about the electron's electric field, and we should distinguish between the near and far field.

The electrons' electric field's (near field) force is mediated by virtual photons, they are just a mathematical way to describe this force. These are not real photons and are not real particles.

Though, the electric field (near field) extends with the speed of light, so it is not instantaneous.

In your case, since the electrons are stationary, and are already there, they already have a near field extended (around a certain position in space), and if the two electrons are close enough, they will feel measurable repulsion as you suggest.

Now the reason they repel each other instantly is because the near field they create is already there, always, and cannot be turned off. This way you cannot test the speed of these interactions.

The way to test what you are asking for, is with electric charges (artificial, man-made), that can be turned off/turned on. Once you put two of these charges close enough, you can test, what you are asking, that is how fast will these near fields interact?

So your question is basically, after you turn on the charges, how soon will they interact and repel?

The answer is, after you turn on the charges, the near field (electric) extends in spherical shape in space with the speed of light. So depending on their distance, it might take a while until they feel the other one's near field.

Let's disregard that in your question you are talking about distances of 300 000 km, which is too far away for man-made electric charges to create a near field strong enough to feel measurable repulsion. Let's say that these charges are 300 000 km apart. Let's say that we have strong enough electric fields, that will create a near field strong enough so that it will have a measurable effect 300 000 km away on the other charge.

Now let's say that we can time the charges to turn on simultaneously at t0. The near fields of the charges will extend with speed c. The two fields will not meet half way, at 150 000 km distance, because of the correct comments and because two near fields will not effect each other, but they will obey the principle of superposition, they will add without interacting.

So the field of one electromagnet will reach the other electromagnet at 300 000 km, in 1 second, and will start repelling it.

Answer 3

You actually do, the classical-classical model studied in electrostatics doesn't take it into account. In reality it's not instant as Quantum Field Theory (QFT) tells us. For electrostatic potential, it travels usually at the speed of light through the medium.

Photons, the elemental particles of "light" are the "middle men" of the electromagnetic force. Light is way more general than just "visible light", When you have two charges, the only way they know about each other is through photons.