# Transverse linear and orbital angular momenta of beam waves and   propagation in random media

**Authors:** Mikhail Charnotskii

arXiv: 1705.04773 · 2018-01-17

## TL;DR

This paper analyzes the transverse linear and orbital angular momenta of beam waves, showing their behavior in free space and random media, and clarifying the role of optical vortices and coherence in intrinsic OAM.

## Contribution

It provides a new coherence-based framework for understanding TLM and OAM, demonstrating their conservation properties and fluctuations in various media.

## Key findings

- Total TLM and OAM are conserved in free space.
- In inhomogeneous media, TLM and OAM are conserved on average but fluctuate.
- Twisted Gaussian beams can have continuously tunable intrinsic OAM.

## Abstract

For paraxial propagation of scalar waves the classic electromagnetic theory definition of transverse linear (TLM) and orbital angular (OAM) momenta of the beam wave are represented in terms of the coherence function. We show in examples that neither the presence of optical vortices is necessary for the intrinsic OAM, nor does the presence of optical vortices warrant the non-zero intrinsic OAM. The OAM is analyzed for homogeneously coherent and twisted partially coherent beam waves. A twisted Gaussian beam has an intrinsic OAM with a per-unit power value that can be continuously changed by varying the twist parameters. Using the parabolic propagation equation for the coherence function, we show that both total TLM and OAM are conserved for the free-space propagation, but not for propagation in an inhomogeneous medium. In the presence of the random inhomogeneous medium, the total TLM and OAM are conserved in average, but the OAM fluctuations grow with the propagation path. This growth is slower for beams with rotation-symmetric irradiance.

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Source: https://tomesphere.com/paper/1705.04773