Violation of Newton's Third Law

In summary: Newton's 3rd law is necessarily violated by any relativistic theory (except in special cases). Standard Maxwell electrodynamics and general relativity are examples. I suppose you could wiggle out of it by making contorted definitions, but the usual ones show very easily that Newton's 3rd law cannot be exact.In summary, it has been shown that Newton's Third Law is necessarily violated by any relativistic theory, such as Standard Maxwell electrodynamics and general relativity. This is due to the finite time interval during which two objects, A and B, are completely ignorant of each other's actions. This results in a freedom of motion and a difference in forces felt at a particular instant, which contradicts the equal and opposite
  • #1
damitr
15
0
Are there any examples of violation of Newton's third law?
The two examples that I know are :
1) Two masses moving relativistically apart from each other.
2) Two charges moving in mutulally perpendicular directions.
Can anybody further elaborate on these exmaples with proper explanation and any other examples in which the third law is violated.
 
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  • #2
damitr said:
Are there any examples of violation of Newton's third law?
The two examples that I know are :
1) Two masses moving relativistically apart from each other.
2) Two charges moving in mutulally perpendicular directions.
Can anybody further elaborate on these exmaples with proper explanation and any other examples in which the third law is violated.

Sorry? How are these two examples "violate" Newton's 3rd Law? And why just that law, considering all 3 Newton's laws are one of the SAME?

Zz.
 
  • #3
I think the second example is mentioned in Goldstein's classical mechanics textbook. When two charges are in motion so as to "cross a T", they do not experience "equal and opposite" forces from their interaction. This is a result of the fact that EM forces do not generally point in the direction of the line that joins the particles in question.
 
  • #4
ahrkron said:
I think the second example is mentioned in Goldstein's classical mechanics textbook. When two charges are in motion so as to "cross a T", they do not experience "equal and opposite" forces from their interaction. This is a result of the fact that EM forces do not generally point in the direction of the line that joins the particles in question.

But isn't this more to do with the retardation effects than "violation of the 3rd law"?

Zz.
 
  • #5
damitr said:
2) Two charges moving in mutulally perpendicular directions.

That's because the electromagnetic field carries both momentum and energy.
 
  • #6
Violation of Newton's Third Law.

The examples that I have quoted are from the book Elementary Physics by I. P. Guruskii (Mir Publishers 1987) pg. 55.

How do these examples violate the law?

That is what I want to know ...

The book does not give any explanation for these 'violations', nor does it give any further examples. Does anybody know about a reference which discusses the 'violations' of the law in much details.
 
  • #7
As we all know Newton's Third Law is:

Forces occur in equal and opposite pairs: whenever
object A exerts a force on object B, object B must also
be exerting a force on object A. The two forces are
equal in magnitude and opposite in direction.
This can be shown as;

F(A on B) = –F (B on A)

So far, no violation of the third law has ever
been discovered, whereas the first and second laws were shown to have
limitations by Einstein and Planck etc... but there is definatly no record of any violation of the 3rd law

Hopefully this will put your mind at rest:smile: :smile:
 
  • #8
Newton's 3rd law is necessarily violated by any relativistic theory (except in special cases). Standard Maxwell electrodynamics and general relativity are examples. I suppose you could wiggle out of it by making contorted definitions, but the usual ones show very easily that Newton's 3rd law cannot be exact.

Think about two objects separated by a considerable distance. At any instant of time, the impossibility of faster than light signalling requires that particle A cannot know what particle B is doing at that time. There is actually a finite time interval during which A is completely ignorant of B, and vice versa. During this window, either particle is free to do whatever it wants (within the laws of physics) without immediately affecting the other one. This freedom of motion translates into a (usually small) freedom in the forces felt at the particular instant of time we are considering. This implies violations of the 3rd law.

To be more specific, let A and B be initially fixed a distance d apart. At a time less than d/c in past, A starts moving. Since the field sourced by B is not homogeneous, the force exerted on A depends on exactly how it moves. But the field sourced by A around B has not (yet) changed, so the force felt by B is independent of A's motion (for a short time). The force on A therefore varies while the force on B does not. The two cannot be always be equal and opposite.

By the way, this violation is exactly what is needed for bodies to exert net forces and torques on themselves. This most often arises in discussions of radiation reaction effects, although it usually isn't introduced in exactly this way. The math gets ugly very quickly, but it does work out to be the same as derivations using energy-momentum conservation.
 
  • #9
"The field sourced by A"? You mean like the gravitational field or the electromagnetic field? What you have shown is that there cannot be an "instantaneous" reaction at B to a change in position of A. It is certainly well know that a change in the position of a charged particle at A, causing a change in the electromagnetic field, does not effect B until a certain time has elapsed- the distance between A and B divided by the speed of light because waves in the electromagnetic field ARE light. It is firmly believed, but, I think, not yet supported by direct experimental evidence that changes in the gravitational field are also transmitted at the speed of light. Pretty much what your argument implies. It certainly does NOT contradict Newton's third law.
 
  • #10
HallsofIvy said:
"The field sourced by A"? You mean like the gravitational field or the electromagnetic field?

Yes.

What you have shown is that there cannot be an "instantaneous" reaction at B to a change in position of A.

Yes.

It certainly does NOT contradict Newton's third law.

Huh? Yes it does. My example showed that the force exerted "by B on A" at any fixed time can be varied without affecting the force "by A on B." The two obviously can't be equal and opposite if it's impossible for them to even be perfectly correlated. If you say that doesn't violate Newton's 3rd law, I'd like to know what version of it you're thinking of.
 
  • #11
Also, this hardly takes sophisticated arguments. Every E&M book gives an example of a situation where forces between two particles are not equal and opposite. I don't understand the point of Zz's dismissal that it's from "retardation effects." So what? That's an important part of Maxwell's theory. The 3rd law states that the forces should be equal and opposite, but they're not. So it's wrong. Of course it's a pretty good approximation in most situations, but that's not what we're talking about.
 
  • #12
Stingray said:
Also, this hardly takes sophisticated arguments. Every E&M book gives an example of a situation where forces between two particles are not equal and opposite. I don't understand the point of Zz's dismissal that it's from "retardation effects." So what? That's an important part of Maxwell's theory. The 3rd law states that the forces should be equal and opposite, but they're not. So it's wrong. Of course it's a pretty good approximation in most situations, but that's not what we're talking about.

Er... So what?

What is applied via the retarded effects are NOT within the realm of what is described via the three Newtonian Laws. If we extend it further, we can find MORE things that are not accurately described by these laws. So why pick on the 3rd Law in particular?

Newtonian laws assume instantaneous, action-at-a-distant effects. They do not take into account retarded effects. Elementary E&M don't either until you start considering the dynamics of the field equations! So to say that the 3rd Law fails when it is applied to a situation it wasn't MEANT to be applied is puzzling. That's like accusing that Thermodynamics 2nd Law is being violated under certian non-equilibrium conditions. What gives? It wasn't meant to be applied there in the first place!

Zz.
 
  • #13
Ok, I understand you now. Our disagreement was just semantics.
 
  • #14
Here's a applicable quote from Goldstein's "Classical mechanics", pg 7.

Note that the conservation of linear momentum in the absence of applied forces assumes that the weak law of action and reaction is valid for the internal forces. The conservation of the total angular momentum of the system in the absence of applied torques reqiures the validity of the strong law of action and reaction - that the internal forces in addition be central. Many of the familiar physical forces, such as that of gravity [ed note: Newtonian gravity[end note], satisfy the strong form of the law. But it is possible to find forces for which action and rection are equal even though the forces are not central forces. In a system involving moving charges, the forces between the charges predicted by the Biot-Savart law indeed may violate both forms of the action and reaction law. Equations (textbook ref's omitted) are not applicable in such cases, at least in the form here given. Usually it is then possible to find some generaliztion of P or L that is conserved. Thus, in an isolated system of moving charges, it is the sum of the mechanical angular momentum and the electromagnetic "angular momentum" of the field that is conserved.
 
  • #15
In a way, we can equate Newton's 3rd law with "conservation of momentum". Indeed, if the "force on A" is dp1/dt and the "force on B" is dp2/dt and one says that these forces must be equal and opposite, this means that:
d(p1+p2)/dt = 0, so p1+p2 is constant.
The examples of relativistic charges not exerting "equal and opposite" forces on each other is of course correct, but it is not because "Newton's third law" is failing, it is because we've missed a player in the field (:smile:): the EM field itself.
So we naively think that particle A is exerting a force on particle B (Newtonian action at a distance), but we're missing that particle A is in fact NOT interacting with particle B, but only with the local EM field, and that this local EM field has its own dynamics, which results in the end in it interacting with particle B.
So this is in fact equivalent with a totally "Newtonian" picture where particle A hits particle C, which flies with finite velocity towards particle B.
If you forget to include particle C, you will find a "violation of Newton's third law" when particle C is travelling.
cheers,
Patrick.
 
  • #16
Going back to the original question, if you take a pair of charges at a 45 degree angle, and do a "Loerntz boost", the force between the charges initally obeys both the strong and weak forms of the third law (as per Goldstein's terminology), as the forces are equal, opposite, and on a direct line between the charges.

If you do a "Lorentz boost" to a new frame, the force between the charges satisfies the weak law, but not the strong law. This means that the forces are equal and opposite, but no longer on a direct line between the charges in the frame. (Note that we are talking about the 3-forces here!).

See the attached diagram for how it all turns out.

This gives rise to a rather obscure paradox in special relativity known as the "lever paradox", whereby internal forces contribute to the angular momentum of a system.

http://scitation.aip.org/getabs/servlet/GetabsServlet?prog=normal&id=AJPIAS000043000007000615000001&idtype=cvips&gifs=yes [Broken]
 

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  • #17
pervect said:
Here's a applicable quote from Goldstein's "Classical mechanics", pg 7.

The quote from Goldstein applies to angular momentum - not to linear momentum. And sure enough, in the usual example of two charged particles moving apart at right angles angular momentum is conserved. But maybe linear not? The only escape there is the A.q factor in the momentum of a charged particle. Works in some cases - but not all :wink:. On average in a plasma there will be momentum conserved and energy at any rate, though.
 
  • #18
jtbell said:
That's because the electromagnetic field carries both momentum and energy.

Funny: all those examples in Goldstein, Feynmann, Griffith et al. consider only the obvious case of charged particles in flight. A current in a wire is not like that at all as the EM field cannot be wheeled out as an excuse for non-violation of Newton's Third Law. I.e. the wire is electrically neutral as the same number of electrons enter it as leave per second, and they are balanced by the positive metal ions. So no radial E field. Only E field is along the wire. So the EM field, if it exists at all, would be radial, which does not balance the forces in the planes of the crossing wires.
 

1. What is Newton's Third Law?

According to Newton's Third Law of Motion, for every action, there is an equal and opposite reaction. This means that when an object exerts a force on another object, the second object exerts an equal and opposite force back on the first object.

2. What is an example of a violation of Newton's Third Law?

An example of a violation of Newton's Third Law can be seen in the movement of a rocket. As the rocket's engines push hot gas out of the back of the rocket, the rocket experiences an equal and opposite force in the opposite direction, propelling it forward. However, this does not follow Newton's Third Law as the rocket is not pushing back on anything to create the forward motion. Instead, it is using the reaction force of the hot gas being pushed out.

3. Can forces ever be completely balanced, violating Newton's Third Law?

No, forces cannot be completely balanced as it would violate Newton's Third Law. Even if two objects are exerting equal and opposite forces on each other, there will always be a slight difference in the forces, as they are acting on different masses. This small difference is what causes motion and prevents forces from being completely balanced.

4. Why is Newton's Third Law important in understanding motion?

Newton's Third Law is important because it helps us understand how objects move and interact with each other. It explains why objects accelerate when a force is applied to them and how forces are always equal and opposite. This law is essential in understanding the fundamental principles of motion.

5. Can Newton's Third Law be violated in outer space?

No, Newton's Third Law applies in all environments, including outer space. Even though there may not be surrounding objects to exert a reaction force, an equal and opposite reaction will still occur. For example, astronauts must use jets to maneuver in space, as the force of the jets pushing outwards creates an equal and opposite force propelling them in the opposite direction.

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