Litcius/Paper detail

Rotational Doppler Effect: A Review

Olivier Émile, Janine Émile

2023Annalen der Physik29 citationsDOIOpen Access PDF

Abstract

Abstract Generally, the linear motion between the source of a wave and an observer leads to a linear Doppler effect. It is associated with the linear momentum of the wave. For electromagnetic beams having a circular polarization or an azimuthal phase distribution, the rotation between the source and the observer results in a less well‐known rotational Doppler effect. It is associated with the angular momentum of the wave. This is particularly the case for vortex beams. Here, the various physical insights that are given to explain the origin of the rotational Doppler effect is reviewed. The focus is on different cases where such an effect gives information on the rotational nature of the probed systems, and also on cases where the rotational Doppler effect is useless. Still debated issues and possible applications are then presented.

Topics & Concepts

Doppler effectPhysicsAngular momentumRotation around a fixed axisPolarization (electrochemistry)AzimuthRotation (mathematics)Observer (physics)VortexClassical mechanicsLinear polarizationElectromagnetic radiationOpticsComputational physicsMechanicsQuantum mechanicsLaserMathematicsGeometryPhysical chemistryChemistryOrbital Angular Momentum in OpticsParticle accelerators and beam dynamicsQuantum and Classical Electrodynamics