by alter-ego » Wed Aug 02, 2023 12:14 am
Chris Peterson wrote: ↑Tue Aug 01, 2023 10:47 pm
alter-ego wrote: ↑Tue Aug 01, 2023 10:38 pm
Chris Peterson wrote: ↑Tue Aug 01, 2023 9:19 pm
But photons don't slow down. They only have one speed... c.
Actually they do. Strictly speaking, "c" specifies the velocity only within a vacuum. The speed of light within a material having index of refraction n is the speed of light in a vacuum ÷ n (c/n). Also, Cherenkov radiation occurs when a charged particle travels faster than light in a medium. The published standard velocity for c is always within vacuum. Measured within our atmosphere (STP conditions), will yield a velocity that is 0.02899% slower the value of "c".
Photons only travel in a vacuum. Once they encounter matter, they scatter, which (in terms of QM) is a process of absorption and re-emission, and that's why we see the "speed of light" as less than c outside of a vacuum. The photons themselves can only travel at c, like any massless particle.
Yeah, the devil's in the details for the source of apparent photon slowdown. Given an atom's quantized orbitals, how do you explain a continuum of reemitted frequencies / energies? I.e, this absorption-reemission process in media works for all frequencies of light. Given our current physics knowledge, Quantum Mechanics has the final say, and I agree the nitty-gritty is in the photon / atom(s) interactions. However, the concept of phase velocity's dependence on the refractive index (c/n) is a useful and practical view on light propagation in media (including Schnell's Law), and the specific time-delay details don't change the observed parameters.
This reminds me of earlier discussions attempting to describe interference in classical and QM formats.
[quote="Chris Peterson" post_id=332682 time=1690930024 user_id=117706]
[quote=alter-ego post_id=332680 time=1690929532 user_id=125299]
[quote="Chris Peterson" post_id=332673 time=1690924743 user_id=117706]
But photons don't slow down. They only have one speed... c.
[/quote]
Actually they do. Strictly speaking, "c" specifies the velocity only within a vacuum. The speed of light within a material having index of refraction n is the speed of light in a vacuum ÷ n (c/n). Also, Cherenkov radiation occurs when a charged particle travels faster than light in a medium. The published standard velocity for c is always within vacuum. Measured within our atmosphere (STP conditions), will yield a velocity that is 0.02899% slower the value of "c".
[/quote]
Photons only travel in a vacuum. Once they encounter matter, they scatter, which (in terms of QM) is a process of absorption and re-emission, and that's why we see the "speed of light" as less than c outside of a vacuum. The photons themselves can only travel at c, like any massless particle.
[/quote]
Yeah, the devil's in the details for the source of apparent photon slowdown. Given an atom's quantized orbitals, how do you explain a continuum of reemitted frequencies / energies? I.e, this absorption-reemission process in media works for all frequencies of light. Given our current physics knowledge, Quantum Mechanics has the final say, and I agree the nitty-gritty is in the photon / atom(s) interactions. However, the concept of phase velocity's dependence on the refractive index (c/n) is a useful and practical view on light propagation in media (including Schnell's Law), and the specific time-delay details don't change the observed parameters.
This reminds me of earlier discussions attempting to describe interference in classical and QM formats.