Submitted by TheFeshy t3_11381g0 in askscience

Let's say we've got light entering a cubic piece of glass, at some angle less than 90 degrees. When it enters, it will be bent at some angle relative to its original path. When it exits, it will resume traveling at its original direction. During this time it will also slow down. (I watched this video explanation as to how this process works.)

Photons have no mass, but they do carry momentum.

During the time the light is inside the glass (let's say it's a very short burst or a very large piece of glass), it's momentum vector is different than when it is traveling in the (for the sake of simplicity) vacuum outside. I have no idea how its momentum is affected by the speed changes, but certainly it would be affected by the direction change. And the conservation of momentum says that this momentum should be exchanged with the glass block.

Now obviously the amounts involved would be minuscule and likely undetectable, given any reasonable source of light and piece of glass. But I'm trying to see if I understand the theory correctly.

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rootofallworlds t1_j8p7aqi wrote

Yes, by conservation of momentum if light is refracted in a way that's not symmetric, momentum must be imparted to the lens. It doesn't even need to be a single pulse - a prism will refract light asymmetrically, and an off-axis section of a spherical-surfaced lens will do it.

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Chemomechanics t1_j8qimev wrote

I did a PhD involving this. Yes, light passing from one medium to another gives the interface a momentum kick. (Edit: example video, not mine.)

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GooseMuckle t1_j8qn81o wrote

Yes! This effect is used for laser cooling. The momentum from a photon can be imparted to an atom; if done in the right way a cloud of atoms can be cooled to a few billionths of a degree above absolute zero. One cool application of this technology is optical clocks, which form the most precise clocks in existence.

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Chemomechanics t1_j8rqj4n wrote

As I recall, the energy is split between absorption, reflection, and refraction. The frequency of the light wave stays the same; its speed changes. Remember that we’re talking about light interacting with matter, rather than lone photons in a vacuum.

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thickener t1_j8rw9kz wrote

This answer got me wondering, if a photon could somehow enter an atmosphere, pass through water, then head back into the vacuum of space, does it “re-accelerate” to “full” lightspeed? How does that work?

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Chemomechanics t1_j8snwzw wrote

The medium plays a part in the momentum transfer, yes.

The net force on a spherical body isn't zero for a single beam because the beam changes shape moving through it, so the refractive details are different on either side.

But for two counterpropagating beams, which is what I used, the left–right forces do balance out, leaving an internal tensile load that stretches a compliant medium. You don't notice this in everyday situations with macroscale objects because they're stiff and the light is weak.

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Fallacy_Spotted t1_j8zjks2 wrote

I don't know. I am a normal dude in IT that spends too much time on the internet. I have a middling understanding of this stuff and am curious. If a refractory medium like a lens behaves differently than a filter that would be interesting. 😁

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