Spin of the Photon: Relativity and Angular Momentum

In summary: You can't visualize it as a rotating material object with some radius r. You can draw a diagram showing circular polarization, with a vector sweeping around in a circle, but that vector is a field vector; it has units of field strength, not units of distance.
  • #1
scope
61
0
hi,

if i understand relativity well, in our frame of reference a photon does not change(infinite time dilation). then if we try mathematically to describe its spin as an intrinsic angular momentum, then there should be no observed angular momentum in our frame of reference because this angular momentum would be at the event horizon and time stops at the event horizon in our reference frame. is it correct?
thank you for your reply!
 
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  • #2
What event horizon? Are you talking about Hawking radiation?
 
  • #3
See any of the zillion threads about how a photon doesn't have a "frame of reference" in the usual sense.

This doesn't prevent photons from having an affine parameterization. There's a handful of threads that discuss this, too, though not as many as the first. A photon doesn't experience time as its worldline is null, but you can still order events along it's worldline in a sequence by an "affine parameter", even though it's a null worldline (and usually a null geodesic worldline).
 
  • #4
DaleSpam said:
What event horizon? Are you talking about Hawking radiation?

no, the event horizon from special relativity
 
  • #5
pervect said:
See any of the zillion threads about how a photon doesn't have a "frame of reference" in the usual sense.

This doesn't prevent photons from having an affine parameterization. There's a handful of threads that discuss this, too, though not as many as the first. A photon doesn't experience time as its worldline is null, but you can still order events along it's worldline in a sequence by an "affine parameter", even though it's a null worldline (and usually a null geodesic worldline).

thank you, but i do wonder about the spin of the photon. in OUR reference frame, do we see the photon spinning or not, if we apply mathematics?
by the way how does spin transform under Lorentz transformations?

thank you for your reply!
 
  • #6
scope said:
no, the event horizon from special relativity
SR does not have the usual event horizons.
 
  • #7
scope said:
thank you, but i do wonder about the spin of the photon. in OUR reference frame, do we see the photon spinning or not, if we apply mathematics?
A spin of +1 along the direction of motion would look like circularly polarized light, with the polarization rotating in the clockwise direction as viewed along the direction of motion (from behind).
 
  • #8
bcrowell said:
A spin of +1 along the direction of motion would look like circularly polarized light, with the polarization rotating in the clockwise direction as viewed along the direction of motion (from behind).

thank you for your great reply. but is it possible that some velocity of this polarization(spin) reaches superluminal speeds, since if we try to interpret the half-integer spin of the electron for a non-zero radius, then it can lead to velocity at this radius that is faster than light(thats why spin causes a problem of definition). Or there is a clear difference between the photon spin and the electron spin regarding this point?
 
  • #9
scope said:
thank you for your great reply. but is it possible that some velocity of this polarization(spin) reaches superluminal speeds, since if we try to interpret the half-integer spin of the electron for a non-zero radius, then it can lead to velocity at this radius that is faster than light(thats why spin causes a problem of definition). Or there is a clear difference between the photon spin and the electron spin regarding this point?

You can't visualize it as a rotating material object with some radius r. You can draw a diagram showing circular polarization, with a vector sweeping around in a circle, but that vector is a field vector; it has units of field strength, not units of distance.

A similar confusion can occur when you talk about an ordinary plane-polarized EM wave. If you believed that something was moving through space along a sinusoidal path, then its velocity would be >c.
 
  • #10
ok, so if i understand well, even if spin causes polarization, polarization is not the rotation described by spin, and nothing describes the spin rotation physically?
 
  • #11
scope said:
ok, so if i understand well, even if spin causes polarization, polarization is not the rotation described by spin, and nothing describes the spin rotation physically?
Yes, and it's the same for the others particles, not for photons only: there is no (accepted) physical model of spin.
 
  • #12
Some good insights into spin here:
http://en.wikipedia.org/wiki/Particle_spin

Spin effects show themselves as in Pauli exclusion and polarization (described already) and as a degree of particle freedom...
The spin of an elementary particle is a truly intrinsic physical property, akin to the particle's electric charge and rest mass.

The same article notes: "Quantum mechanics states that the component of angular momentum measured along any direction (say along the z-axis) can only take on the values..." so I guess in this sense we do measure spin rather directly...
 
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  • #13
scope said:
hi,

if i understand relativity well, in our frame of reference a photon does not change(infinite time dilation).

I think it's backwards - in a photon's own "reference" (which cannot exist but for simplicities sake) time does not pass. In our frame of reference or from the frame of reference of any massive object photons do take time to reach destinations.
 

1. What is the spin of a photon?

The spin of a photon refers to its intrinsic angular momentum, which is a measure of how the photon rotates around its own axis as it travels through space. It is a fundamental property of the photon and is always equal to 1.

2. How is the spin of a photon related to relativity?

According to the theory of relativity, the laws of physics should be the same for all observers regardless of their relative motion. Therefore, the spin of a photon must also be the same for all observers, regardless of their frame of reference.

3. Can the spin of a photon change?

No, the spin of a photon is a conserved quantity and cannot change. This means that the photon will always have a spin of 1, regardless of any interactions or observations.

4. How does the spin of a photon affect its behavior?

The spin of a photon plays a crucial role in determining its polarization, which is the orientation of the photon's electric and magnetic fields. This, in turn, affects how the photon interacts with other particles and how it is detected by instruments.

5. What is the significance of the spin of a photon in quantum mechanics?

In quantum mechanics, the spin of a photon is used to describe and explain various phenomena, such as the spin-1/2 nature of fermions and the spin-0 nature of bosons. It is also a key component in the study of quantum entanglement and the development of quantum technologies.

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