Multi-modes Bessel-Gaussian-Orbital Angular Momentum Beams Quantum Holography

TL;DR

This paper introduces a quantum holography scheme using multi-mode Bessel-Gaussian beams and entangled photons, enhancing encoding capacity and noise resistance over traditional methods.

Contribution

It presents a novel OAM quantum holography approach leveraging multi-mode Bessel-Gaussian modes and entanglement for improved multiplexing and noise robustness.

Findings

The scheme effectively realizes OAM quantum holography with Bessel-Gaussian modes.

It enhances multiplexing capacity by adding mode degrees of freedom.

Quantum correlations improve noise resistance in holography.

Abstract

We propose an orbital angular momentum (OAM) quantum holography scheme based on multi-mode Bessel-Gaussian (MBG) beams. Entangled photon pairs are generated through spontaneous parametric down-conversion (SPDC) process, and the axis prism parameters and topological charges of the idler photons are used for encoding to construct Bessel-Gaussian quantum selective holograms; then, the corresponding mode parameters carried by the signal photons are used for correlated decoding and information reconstruction. Theoretical analysis and numerical simulation results show that this scheme can effectively realize OAM quantum holography based on Bessel-Gaussian modes encoding. Compared with traditional single OAM encoding methods, our scheme introduce an additional mode degrees of freedom, which can enhance multiplexing dimension and encoding capacity; at the same time, relying on the non-classical correlation characteristics of entangled photons, quantum holography has a potential advantages in noise-resistance performance.