How does the wavelength change the amount of refraction?

AI Thread Summary
The discussion highlights that the index of refraction varies with wavelength, leading to greater refraction of green light compared to red light when passing through a prism. This phenomenon occurs because shorter wavelengths experience higher indices of refraction. The conversation also notes that while prisms visibly demonstrate this effect, it is not universally applicable, as nondispersive media do not exhibit frequency-dependent refraction. The shape of the medium, such as prisms or raindrops, influences the visibility of dispersion effects. The question of nondispersive media beyond a vacuum is raised, prompting further exploration of the topic.
Muggo
Using a green laser instead of a red laser seems to change the way the ray changes during refraction. Why is that so?
 
Science news on Phys.org
A material's index of refraction is wavelength/frequency dependent and typically increases as the wavelength decreases. Hence why green light is refracted more than red light when passing through something like a prism.
 
Muggo said:
Using a green laser instead of a red laser seems to change the way the ray changes during refraction. Why is that so?
Just as an aside, have no you not ever seem a prism in action? It splits a white light beam into a spectrum of colors using exactly the mechanism described by Drakkith, so it's hardly surprising that you are getting the results you are getting.
 
I could throw the question back to the OP and ask why he would expect the refraction to be the same for all frequencies. The spectrum of visible light covers about an octave of frequencies so it's hardly surprising that a phenomenon which involves 'lag' of waves would be frequency dependent.
 
I feel I should point out that with a prism, this is obvious but it's not a general rule. If the propagation medium is nondispersive, for example, then there's no frequency dependence for the phase velocity and therefore refraction.
 
boneh3ad said:
If the propagation medium is nondispersive,
That would depend upon the range of frequencies involved. Nothing works the same from DC to daylight.
 
boneh3ad said:
I feel I should point out that with a prism, this is obvious but it's not a general rule. If the propagation medium is nondispersive, for example, then there's no frequency dependence for the phase velocity and therefore refraction.

The only reason it's obvious with a prism is because of its shape, in other words the shape is such that the separation of the wavelengths can be quite large. The same goes for other shapes such as spheres, eg raindrops forming rainbows, and lenses which suffer from chromatic aberation.
With other shapes, for example a parallel sided glass block, the separation due to dispersion can be so small that it may not be noticeable. But even with normal incidence where the there is no separation there is still dispersion because the different frequencies travel at different speeds.
But and this is the main reason I replied to this, are there any nondispersive media apart from a vacuum?
 

Similar threads

Why does the amount of Refraction depend on wavelength?
Replies
1
Views
1K
A Reflectivity with gradient in refractive index
Replies
6
Views
2K
B Geometrical Optics: Explaining the Effects of Small Wavelengths
Replies
3
Views
2K
Critical angle (symmetry of refraction) confusion
Replies
5
Views
2K
Refraction of Light Wave: What Causes It?
Replies
16
Views
4K
Refraction, wavelength and frequency
Replies
11
Views
6K
How does an index of refraction affect the EM field?
Replies
6
Views
1K
Is there a limit to how steep the refractive index gradient can be
Replies
6
Views
2K
Refractive index in the ultraviolet region
Replies
3
Views
2K
Refraction-Speed difference at different wavelengths
Replies
10
Views
3K

Hot Threads

Recent Insights

Back
Top