Uncovering the Mystery of Photons in Orbit: Factors Affecting Their Movement"

[nuby]

What would be required to cause photons to orbit an object?

 

[Nabeshin]

A lot of gravity.

 

[nuby]

Is that the only force that interacts with photons?

 

[Nabeshin]

Well certainly electromagnetism can't interact with it because well... photons carry electromagnetism. Don't know about the strong or weak nuclear forces though.

 

[AdamPhysics]

gravity

Gravity would more than likely dominate, unless you worry about an atmosphere and then scattering or density variations, as well as refractive index variations (optical fiber) could trap the light. Black holes etc.. trap light through gravitational force

 

[dst]

Anything that makes the path of least time in the form of a circle. I wonder if that's even possible since then it becomes essentially infinite length.

 

[George Jones]

Photons can orbit black holes.

A photon orbit around a spherical black hole has r coordinate 50% greater than the r coordinate of the event horizon.

 

[Crosson]

Well certainly electromagnetism can't interact with it because well... photons carry electromagnetism. Don't know about the strong or weak nuclear forces though.

I just want to point out that the reason photons don't interact with the electromagnetic force is not because they are the carriers of that force but rather because they are themselves charge neutral.

Compare this to the color force, which gives rise to the strong force in the nucleus, where the gluons that carry the force between variously colored quarks are themselves colored which gives rise to pure gluon interactions called glueballs and making the theory nonlinear.

I agree that a ray of light can orbit a black hole, so can even a light packet, but getting it to happen to a single photon would likely require carefully controlled laboratory conditions.

 

[nuby]

I agree that a ray of light can orbit a black hole, so can even a light packet, but getting it to happen to a single photon would likely require carefully controlled laboratory conditions.

I'm curious how much force would be required for this, any ideas?

 

[nuby]

Is this known, or impossible to figure out?

 

[nuby]

Do photons interact with the nuclear strong force?

 

[lightarrow]

What would be required to cause photons to orbit an object?

To inject light into a circular glass fiber?

 

[nuby]

Seems like the gravity to hold a photon in orbit around a black hole should be known? Is it?

 

[DrGreg]

Seems like the gravity to hold a photon in orbit around a black hole should be known? Is it?

George Jones has already given the answer, if only you'd realize it, in post #7.

Find yourself a non-rotating spherical black hole of mass M, and carefully launch a photon into a circular orbit with circumference

$$\frac {6 \pi G M} {c^2}$$​

If you aim the photon in exactly the right direction, and if it never collides with anything and if there is nothing else in the Universe, then the photon will go into orbit.

However, photon orbits are unstable, so if you can't meet all the above conditions (and in practice you can't), the photon will eventually spiral out of orbit (inwards or outwards).

Reference: "Black hole: Photon sphere" on Wikipedia.

 

[DaveC426913]

Why would a photon's orbit be any less stable than a regular mass orbiting a regular body?

 

[kanato]

Because a regular mass can change speed. If it moves closer to the other object, the gravitational force will increase but its speed will also increase, so it won't end up crashing into the massive body. Photons can't increase or decrease speed, so if a photon is not at the ideal radius, then it won't get into a circular orbit because the attraction to the massive body is increased at a radius smaller than the circular orbit radius.

 

[DaveC426913]

Because a regular mass can change speed. If it moves closer to the other object, the gravitational force will increase but its speed will also increase, so it won't end up crashing into the massive body. Photons can't increase or decrease speed, so if a photon is not at the ideal radius, then it won't get into a circular orbit because the attraction to the massive body is increased at a radius smaller than the circular orbit radius.

Right. Photons cannot hold elliptical orbits.

 

[George Jones]

Why would a photon's orbit be any less stable than a regular mass orbiting a regular body?

For spherical black holes, there are unstable circular orbits of massive particles, as well as stable circular orbits.

For spherical black holes, "photon" orbits occurs only at $r = 1.5R_S$, where $R_S$ is the Schwarzschild radius of the event horizon. These orbits all are unstable.

Unstable circular orbits for massive particles occurs for $1.5R_S < r < 3R_S$.

Stable circular orbits for massive particles occurs for $r > 3R_S$.

The class of unstable circular orbits for massive particles can be divided into orbits that are very unstable, and orbits that are somewhat unstable.

 

[MeJennifer]

The class of unstable circular orbits for massive particles can be divided into orbits that are very unstable, and orbits that are somewhat unstable.

As an aside, all orbits of objects of mass decay under GR.

 

[George Jones]

As an aside, all orbits of objects of mass decay under GR.

I'm not sure what you mean.

 

[yuiop]

As an aside, all orbits of objects of mass decay under GR

I'm not sure what you mean.

.

I guess Jennifer is referring to the fact that neutron stars orbiting each other are observed to have orbits that are decaying due to the loss of energy radiated as gravity waves. While this effect is difficult to measure even for neutron stars, it presumably exists for all gravitationaly orbiting objects.

 

[nuby]

What is the maximum 'number' of photons you can inject into the orbit?

 

[Crazy Tosser]

Anything that makes the path of least time in the form of a circle. I wonder if that's even possible since then it becomes essentially infinite length.

I think that the principle of least time can only be applied when the space is more or less not curved.

But then what the hell would the actual electromagnetic fields look like...

 

[DaveC426913]

What is the maximum 'number' of photons you can inject into the orbit?

The same number that you can inject into any other space: there is no limit. Photons do not take up space.