Zahidur said:However, I've also read that light speed is constant everywhere
No. It isn't a Gravitational /GR effect; it's an electromagnetic effect. Dense materials have more densely packed charges which interact with an EM wave going through.Zahidur said:Is it because the object is more dense and therefore space-time is more warped and so it takes longer for light to travel
It isn't a Gravitational /GR effect
Of course. How would a low mass piece of glass hope to slow light down to 0.6c by relativistic effects?Zahidur said:So, is the gravitational effect on the photon too insignificant to be considered (relative to the effect of the electromagnetic force)?
A more precise statement would be "light isn't the same speed through all materials". It is the same in any inertial space through a vacuum. And I believe it would be the same through the same material in any inertial reference space.Zahidur said:Oh right, I just thought they contradicted because if light slows down in other objects then it is no longer traveling at light speed (c) but at some lower speed. So light isn't the same speed everywhere (I now get that it's only the same in a vacuum).
I had to look that one up. turns out it probably wasn't a typo.Zahidur said:Aight sfe.
I don't think that's right. Wouldn't it follow the usual formulas for transforming velocity between different reference frames?FactChecker said:And I believe it would be the same through the same material in any inertial reference space.
I was thinking that there should be no way for any inertial frame to detect an effect of its motion. So measuring the speed of light through any material would be the same as if it was stationary. That is what I meant to say. I think that must be right.Redbelly98 said:I don't think that's right. Wouldn't it follow the usual formulas for transforming velocity between different reference frames?
Yes, as experimentally confirmed by Fizeau in 1851 (approximately, for low speeds).Redbelly98 said:I don't think that's right. Wouldn't it follow the usual formulas for transforming velocity between different reference frames?FactChecker said:And I believe it would be the same through the same material in any inertial reference space.
If you mean the speed of light through a given material relative to an inertial frame in which the material is at rest, then, yes, that will be constant.FactChecker said:I was thinking that there should be no way for any inertial frame to detect an effect of its motion. So measuring the speed of light through any material would be the same as if it was stationary. That is what I meant to say. I think that must be right.
DrGreg said:If you mean the speed of light through a given material relative to an inertial frame in which the material is at rest, then, yes, that will be constant.
Yes, I was assuming that, too.DrStupid said:Only if the medium is homogeneous and isotropic.
Yes. That is what I meant: relative to an inertial frame in which the material is at restDrGreg said:If you mean the speed of light through a given material relative to an inertial frame in which the material is at rest, then, yes, that will be constant.
Light always travels at light speed. But light speed is given by [itex]c=\frac{1}{\sqrt{\epsilon\mu}} [/itex] and thus varies with the medium i travels through. In vacuum, with [itex]\epsilon =\epsilon_{0}[/itex] and [itex]\mu =\mu_{0} [/itex], you get the often-cited value of c (or should we say c0) = 299792458 m/s.Zahidur said:I've been told contradicting ideas about this. I've been told that light doesn't travel at a constant speed everywhere (i.e. light slowing down in speed after entering a more dense medium). However, I've also read that light speed is constant everywhere (i.e. if you could travel close to the speed of light then you would experience warped space-time so light would still travel at light speed relative to you). So which is it or are both these ideas not the whole story?
Svein said:Light always travels at light speed.
Actually, I was stating a tautology (of course light is traveling at light speed - by definition). The problem is to relate "light speed" to other speeds and measurement systems.DrStupid said:That applies to plane waves but light waves don't need to be plane.
Zahidur said:I've been told contradicting ideas about this. I've been told that light doesn't travel at a constant speed everywhere (i.e. light slowing down in speed after entering a more dense medium). However, I've also read that light speed is constant everywhere (i.e. if you could travel close to the speed of light then you would experience warped space-time so light would still travel at light speed relative to you). So which is it or are both these ideas not the whole story?
Svein said:Actually, I was stating a tautology (of course light is traveling at light speed - by definition).
Neither is a medium,show me a medium that is both homogeneous and isotropic and it will probably turn out to be a felt hat.DrStupid said:Actually, reality is not that simple.
At Harvard in 1998, the speed of light was slowed down to 38 miles per hour!PFfan01 said:D. Giovannini, J. Romero, V. Potoček, G. Ferenczi, F. Speirits, S.M. Barnett, D. Faccio, M.J. Padgett,
Spatially structured photons that travel in free space slower than the speed of light,
Science 347 (2015) 857-860).
rude man said:At Harvard in 1998, the speed of light was slowed down to 38 miles per hour!
So?DrStupid said:But that was in an Bose-Einstein condensate and not in free space.
Every medium consists of 99,99999... % vacuum. So, what happens when the light travels inside these "vast areas" of vacuum (as it travels inside this material)? Is its speed slower than c? (And if yes then how is this possible?)Svein said:Light always travels at light speed. But light speed is given by [itex]c=\frac{1}{\sqrt{\epsilon\mu}} [/itex] and thus varies with the medium i travels through. In vacuum, with [itex]\epsilon =\epsilon_{0}[/itex] and [itex]\mu =\mu_{0} [/itex], you get the often-cited value of c (or should we say c0) = 299792458 m/s.
See the link in post #5.George K said:Every medium consists of 99,99999... % vacuum. So, what happens when the light travels inside these "vast areas" of vacuum (as it travels inside this material)? Is its speed slower than c? (And if yes then how is this possible?)
I have already read that. However, it doesn't say anything about that. Let's consider the following: Suppose that you have a "transmitter" that emits a photon and a "receiver" that receives this photon, and that the "transmitter" and "receiver" are both located in the vacuum and very close to each other (at a distance similar to the distance between the atoms of a medium). (This "transmitter" and "receiver" could be two atoms of a gas -one transmitting a photon and the other receiving this photon- which happens to be so close to each other.) What is the speed of light in this case? As the photon travels inside the vacuum, it's speed should be c (no matter how short its travel is). If this is correct, then what is the difference between this case and the travel of light inside the "vacuum areas" (i.e. between the atoms) of a medium?DrGreg said:See the link in post #5.
I would say that you are mixing your models up. Photons don't travel from molecule to molecule. The propagation is in the form of waves and individual photons cannot be regarded as 'being' anywhere at any given time. It has been said many times before but you cannot treat photons as little bullets. They are essentially only 'there' when they interact. If the whole wave is being involved than where can you say the individual photons are? Stick a tiny light sensor in the middle of the medium and you can say that, when it 'sees' light, it has interacted with a particular few photons - defining where they are at the time.George K said:what is the difference between this case and the travel of light inside the "vacuum areas" (i.e. between the atoms) of a medium?
Ok, I agree that I should not use the term photon. But actually the question remains. In my example, one atom of the gas emits light (ok, as a wave) and another nearby atom of the gas receives this light (yes, as a wave). What is the speed of light in this case? I suppose that the speed must be c, no matter how close to each other these atoms are (and that's because there is only vacuum between them). Am I right?sophiecentaur said:I would say that you are mixing your models up. Photons don't travel from molecule to molecule. The propagation is in the form of waves and individual photons cannot be regarded as 'being' anywhere at any given time. It has been said many times before but you cannot treat photons as little bullets. They are essentially only 'there' when they interact. If the whole wave is being involved than where can you say the individual photons are? Stick a tiny light sensor in the middle of the medium and you can say that, when it 'sees' light, it has interacted with a particular few photons - defining where they are at the time.
It is not a good idea to try to bend the accepted terms to your own model.
I'm going to throw something else in, here. You are talking about "light" but any model you come up with should also be applicable to 1500m long waves and the shortest of gamma waves.George K said:Ok, I agree that I should not use the term photon. But actually the question remains. In my example, one atom of the gas emits light (ok, as a wave) and another nearby atom of the gas receives this light (yes, as a wave). What is the speed of light in this case? I suppose that the speed must be c, no matter how close to each other these atoms are (and that's because there is only vacuum between them). Am I right?
sophiecentaur said:In a 'condensed' substance, the spacing between atoms / molecules will probably be less than one wavelength of visible light.