I Why tilting a diffraction grating produces tilted dots

AI Thread Summary
Tilting a diffraction grating results in a tilt of the output dots due to the propagation of light as a superposition of plane waves, which affects the angular distribution of the diffracted beams. The discussion highlights confusion around the Ewald sphere and its connection to continuity conditions in diffraction theory. While normal incidence is well understood, the behavior at oblique angles presents challenges that are less commonly addressed in literature. The participants express a desire for clarity on these complex interactions and their implications for understanding diffraction patterns. Overall, the conversation emphasizes the need for deeper insights into the physics of diffraction gratings and their angular effects.
Daniel Petka
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TL;DR Summary
If I send a gaussian laser beam through a diffraction grating at an angle, the dots are tilted and not straight.
Why does tilting a diffraction grating tilt the dots as well? This doesn't make sense to me because the lines are still lines when tilted. Even when I consider the phase and consider the gaussian beam that comes in as a superposition of plane waves, what comes out are dots in a straight line. Thanks for any insight!

My best attempt to make sense of this is to imagine the light behind the grating as an interference of many beams (plane waves actually). Ultimately, the light "doesn't know" what happens before it, it just propagates. This works great at normal incidence, it's called the angular spectrum, but it absolutely fails when the light comes in at an angle

340_2021_7620_Fig4_HTML.png
 
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Hi,

You found the picture, so I suppose you also found the article. (Could have saved us the time to locate it by posting the reference !)

The article goes a long way to answer your questions ....

Daniel Petka said:
Why does tilting a diffraction grating tilt the dots as well? This doesn't make sense to me because the lines are still lines when tilted. Even when I consider the phase and consider the gaussian beam that comes in as a superposition of plane waves, what comes out are dots in a straight line. Thanks for any insight!

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BvU said:
Hi,

You found the picture, so I suppose you also found the article. (Could have saved us the time to locate it by posting the reference !)

The article goes a long way to answer your questions ....



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Sorry for not including the article. The reason why I'm asking this is to understand the Ewald sphere. This is not the first article that I looked into that derives this using the Ewald sphere, so I'm kind of stuck. Forgive me, should have included that in the post. I already have the intuition for the Evald sphere and coupled wave theory at normal incidence - you don't have to worry about the continuity condition E,t1 = E,t2. It's not obvious to me why the continuity condition is connected to the Ewald sphere. That's where I'm struggling
 
Heuberger et al said:
Theories for almost any conceivable configuration other than the two mentioned above are treated in the literature (see, e.g., [2, 3]), but remain widely unknown to most non-specialists.
And I'm afraid I'm a non-specialist :wink:

Interesting topic, though !

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