Optically active materials + Faraday Rotation

In summary, the direction of rotation for a linearly polarised wave due to the Faraday effect is independent of the direction of wave propagation, but for normal optical activity, the direction of rotation can vary depending on the direction of propagation. This is because the magnetic field in the Faraday effect breaks symmetry, while optically active materials have a specific clockwise or anticlockwise rotation.
  • #1
freemind
Hello folks,

I have been told that for a linearly polarised wave, the direction of rotation due to the Faraday effect (caused by a constant magnetic field) is independent of the direction of wave propagation, dependent only upon the direction of the magnetic field. Fair enough. Does this property hold for normal optical activity? Is the direction of rotation the same in an optically active material regardless of direction of propagation?

Thanks.
 
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  • #2
freemind said:
Hello folks,

I have been told that for a linearly polarised wave, the direction of rotation due to the Faraday effect (caused by a constant magnetic field) is independent of the direction of wave propagation, dependent only upon the direction of the magnetic field. Fair enough. Does this property hold for normal optical activity? Is the direction of rotation the same in an optically active material regardless of direction of propagation?

Thanks.

I think that the answer to your question is no (although someone may correct me). The magnetic field (in the Faraday effect) breaks the symmetry of the situation. Suppose you send linearly polarized light (say s-polarized) through a Faraday rotator that rotates the light 45 degrees. If you place a mirror after the rotator that sends it back the way it came, the light will be p-polarized after it goes through the rotator a second time. However, if you replace the rotator with a normal optically active material, the output polarization will be what it was originally (s-polarized). That is why a Faraday rotator (coupled with a polarizer) works as an http://www.eoc-inc.com/leysop/Faraday_optical_isolator_rotators.htm (light can only go one direction). Hope this helps.
 
  • #3
freemind said:
Is the direction of rotation the same in an optically active material regardless of direction of propagation?

Thanks.

If by "direction of propagation", you mean one way or the other along the optic axis, then no, the Farady effect and optically active materials behave differently, as was said above. An optically active material could be said to be either clockwise or anticlockwise, while for the Faraday effect, "clockwise-ness" depends on direction.

If you include directions that are not along the optic axis, the question is a bit more complicated.
 
  • #4
I see how the direction of rotation is dependent upon the direction of propagation. Thanks a lot for the replies.
 

1. What are optically active materials?

Optically active materials are substances that have the ability to rotate the plane of polarization of light passing through them. This phenomenon, known as optical activity, is due to the asymmetrical arrangement of molecules in the material.

2. How does Faraday Rotation work?

Faraday Rotation is a phenomenon in which the plane of polarization of light is rotated when it passes through a material in the presence of a magnetic field. This is due to the interaction between the magnetic field and the electrons in the material, causing a change in the direction of the light's polarization.

3. What are some examples of optically active materials?

Some common examples of optically active materials include sugars, amino acids, and certain types of crystals such as quartz and calcite. These materials are often used in the production of polarizing filters, optical instruments, and other devices that utilize the phenomenon of optical activity.

4. What are the applications of Faraday Rotation?

Faraday Rotation has several important applications in modern technology. It is used in devices such as optical isolators and modulators, as well as in the production of circularly polarized light for use in telecommunications and medical imaging.

5. How is Faraday Rotation measured?

Faraday Rotation is typically measured using a device called a polarimeter, which measures the degree of rotation of the plane of polarization of light passing through a material. The amount of rotation is dependent on the strength of the magnetic field, the thickness of the material, and the wavelength of the light.

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