Conservation of Angular Momentum and the Role of Coordinate Systems

In summary, the angular momentum of a closed system (not subject to outside forces) is constant in time and independent of the coordinate system you choose.
  • #1
aftershock
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Imagine i have a particle in the xy plane rotating in a circle around the z-axis at a constant angular velocity. The angular momentum is r cross p which would give me a constant value at all times, there is no change and it's conserved. However if I was to move the rotating particle higher up and then draw my r vector out from the origin the direction of angular momentum would constantly change as the particle rotated.

So at one chosen origin the angular momentum is constant, but at another chosen origin it changes? If this is true, wouldn't that imply there is a torque and also that there's no torque?
 
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  • #2
Interesting. I agree with everything you say, including your conclusion. But there is nothing paradoxical about the conclusion. It's well known that torque (like angular momentum) depends upon the chosen point about which we calculate it.

Only when we have a system of particles acting on each other by central forces can we say that the sum of angular momenta about any point is constant, and that the resultant torque about any point is zero.
 
  • #3
Philip Wood said:
Interesting. I agree with everything you say, including your conclusion. But there is nothing paradoxical about the conclusion. It's well known that torque (like angular momentum) depends upon the chosen point about which we calculate it.

Only when we have a system of particles acting on each other by central forces can we say that the sum of angular momenta about any point is constant, and that the resultant torque about any point is zero.

Right. The fact that angular momentum is not conserved at every point shows that the system described is physically unrealistic. I'm not sure that "only" when we have a system of particles acting on each other by central forces is the angular momentum constant at every point. For example, an electron in a magnetic field. But even then, if you include the mechanism that is generating the magnetic field as part of the system, angular momentum is conserved at every point.
 
  • #4
There is nothing unrealistic.
In order to have uniform circular motion you need some centripetal force.
The torque of this force is zero in respect to the center of the trajectory but is non-zero in respect to a different point along the axis.
 
  • #5
nasu said:
There is nothing unrealistic.
In order to have uniform circular motion you need some centripetal force.
The torque of this force is zero in respect to the center of the trajectory but is non-zero in respect to a different point along the axis.

It is unrealistic - the angular momentum depends on the coordinate system. Physics is independent of the coordinate system that you choose. By Newton's law, the particle will exert a force on the source of the centripetal force, and this will give rise to an additional angular momentum. The sum of the two will be independent of coordinate system and will be constant in time.
 
  • #6
I suppose we should make sure that we mean the same thing by "unrealistic".
How will this make it unrealistic? What parts are not conform with reality?
 
  • #7
nasu said:
I suppose we should make sure that we mean the same thing by "unrealistic".
How will this make it unrealistic? What parts are not conform with reality?

You will never find a free particle simply rotating in a circle. A free particle will always be traveling in a straight line at a fixed velocity. The angular momentum of such a particle is a constant and is the same in any coordinate system. If you have a particle rotating in a circle, there must be a force on that particle, and there must be a source of that force. By Newton's law, the source exerts a force on the particle, the particle exerts a force on the source. If you just consider the particle alone, its angular momentum will be a function of which coordinate system you choose. If you just consider the source alone, its angular momentum will also be a function of which coordinate system you choose. Only when you calculate the sum of the two angular momenta will it be constant in time, independent of coordinate system.

The angular momentum of a closed system (not subject to outside forces) is constant in time and independent of the coordinate system you choose. If you ever calculate the angular momentum of a system to be changing in time, then you will know that it is not closed - there is some outside force causing it. If you expand the system to include the source of that force, and there are no other forces on that system, then its angular momentum (and linear momentum, and energy) will be constant in time and independent of the coordinate system that you choose.
 
  • #8
Rap said:
You will never find a free particle simply rotating in a circle. A free particle will always be traveling in a straight line at a fixed velocity.
Oh, I see what you mean.
But who implied that you will?
Who said that the particle is free? I did not for sure.
If you just look at the angular momentum of one particle, what you find out is not less realistic than what you get when looking at the system. As long as you know what are you looking at.
 
  • #9
nasu said:
Oh, I see what you mean.
But who implied that you will?
Who said that the particle is free? I did not for sure.
If you just look at the angular momentum of one particle, what you find out is not less realistic than what you get when looking at the system. As long as you know what are you looking at.

I took the OP's statement "So at one chosen origin the angular momentum is constant, but at another chosen origin it changes?" as a question about how the physical principle of angular momentum conservation can hold if it changes with your choice of coordinate system. Maybe I was wrong.
 

1. What is angular momentum?

Angular momentum is a physical quantity that measures the amount of rotational motion an object has. It is a vector quantity, meaning it has both magnitude and direction.

2. What causes confusion about angular momentum?

One common source of confusion about angular momentum is the fact that it is not directly related to an object's speed or velocity, but rather to its position and mass distribution.

3. How is angular momentum calculated?

Angular momentum is calculated by multiplying an object's moment of inertia (a measure of its resistance to rotational motion) by its angular velocity (a measure of how fast it is rotating).

4. What is the difference between angular momentum and linear momentum?

Linear momentum is a measure of an object's motion in a straight line, while angular momentum is a measure of its rotational motion. They are both conserved quantities in a closed system, but they are calculated and behave differently.

5. Why is angular momentum important?

Angular momentum is an important concept in physics because it helps us understand the behavior of rotating objects, such as planets and galaxies. It also has practical applications in engineering and technology, such as in the design of turbines and gyroscopes.

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