Complete characterisation of the azimuthal and radial indices of light fields carrying orbital angular momentum

TL;DR

This paper presents a novel method for the simultaneous measurement of azimuthal and radial mode indices of Laguerre-Gaussian light fields, enabling complete characterization of their complex structure.

Contribution

It introduces a training-based optical system that accurately determines both mode indices of LG beams, including superpositions, with robustness to beam fluctuations.

Findings

Successfully measures both azimuthal and radial indices simultaneously.

Can decompose superpositions into individual mode intensities and phases.

Tolerates fluctuations in beam parameters such as waist size and alignment.

Abstract

The direct determination of the complete transversal state of an electromagnetic field and accompanying mode indices is essential for the proper quantification of all light-matter interactions. In particular light fields with cylindrical symmetry such as Laguerre-Gaussian beams can possess orbital angular momentum, central to a wide range of emergent applications in quantum cryptography, manipulation, astrophysics and microscopy. A wide array of diffractive structures such as arrays of pinholes, triangular apertures, slits, and holograms have all recently been used to measure the azimuthal index L of individual LG beams. However, all these approaches measure only one single degree of freedom of LG beams, neglecting the radial component or P index and are thus not applicable for a priori unknown beams. Furthermore, it is unclear which is the optimal aperture and scheme needed to determine simultaneously the azimuthal and radial indices nor the extent with which such an aperture can tolerate deviations in beam parameters. Here, we demonstrate a powerful approach to simultaneously measure the radial and azimuthal indices of both pure and mixed LG light fields. We show that the shape of the diffracting element used to measure the mode indices is in fact of little importance and the crucial step is training any diffracting optical system and transforming the observed pattern into uncorrelated variables. Modest fluctuations in beam parameters such as waist size and alignment variations can be tolerated in our scheme. Importantly, beam superpositions can be experimentally decomposed delivering the intensity of each mode and their relative phases. Our results demonstrate the complete characterisation of LG beams. The approach can be expanded to other families of beams and represents a powerful method for characterising the optical multi-dimensional Hilbert space.