Faraday rotation is an example of non-reciprocal optical propagation.

There are a few applications of Faraday rotation in measuring instruments.

In the past few years, he discovered giant Faraday rotation in graphene and subsequently demonstrated novel microwave and terahertz devices.

Apart from providing information on sources of radiation and scattering, polarization also probes the interstellar magnetic field via Faraday rotation.

However, when the fibre is put into a spatially varying magnetic field, a phenomenon called Faraday rotation comes into play.

Orthoferrites are transparent, and can modify the polarisation of a beam of light under the control of a magnetic field (Faraday rotation).

Considering the atomic arrangement is different along the (100) and (110) plane, one might think the Faraday rotation is polarization dependent.

They tested the Faraday rotation with and without the plasmonic materials involved and reported the rotation enhancement under light irradiation peaked at 530 nm.

This is called Faraday rotation, and the angle is called the Faraday rotation angle.

Development of Faraday rotation and double pulse techniques.