Phase memory for optical vortex beams

TL;DR

This paper investigates how perfect optical vortex beams retain their phase structure after interacting with random media, providing an analytical model and experimental validation of their phase memory under various disturbance conditions.

Contribution

It introduces the first quantitative analysis of phase memory degradation in perfect optical vortex beams interacting with localized random media, including an analytical model and experimental validation.

Findings

Phase memory persists under certain disturbance regimes.

The spatial correlation length and phase variance influence phase retention.

Numerical simulations and experiments confirm the model's predictions.

Abstract

Optical vortex beams have been under considerable attention recently due to their demonstrated potential for applications ranging from optical communication to particle trapping. Practical problems related to the dependence between their phase structure and the physical size have been addressed by introducing the concept of perfect optical vortex beams. Propagation of these structured beams through different levels of disturbances is critical for their uses. For the first time, we examine quantitatively the degradation of perfect optical vortex beams after their interaction with localized random media. We developed an analytical model that describes how the spatial correlation length and the phase variance of the disturbance affect the phase distribution across the vortex beams. This allows to ascertain the regimes of randomness where the beams maintain the memory of their initial vorticity. Systematic numerical simulations and controlled experiments demonstrate the extent of this memory effect for beams with different vorticity indices.