Realization of doubly inhomogeneous waveplates for structuring of light beams

TL;DR

This paper introduces a method to realize doubly inhomogeneous waveplates using a combination of three standard s-plates, enabling advanced control over light beam properties for structured light applications.

Contribution

It analytically demonstrates that any doubly inhomogeneous waveplate can be implemented with three s-plates, offering flexible design and novel applications in phase and amplitude shaping of light.

Findings

Validated the three-s-plate implementation through numerical simulations.

Proposed new d-plates for phase and amplitude tailoring of light beams.

Demonstrated the creation of higher-order eigenmodes and phase-polarization gadgets.

Abstract

Waveplates having spatially varying fast-axis orientation and retardance provide an elegant and easy way to locally manipulate different attributes of light beams namely, polarization, amplitude and phase, leading to the generation of exotic structured light beams. The fabrication of such doubly inhomogeneous waveplates (d-plates) is more complex, compared to that of singly inhomogeneous waveplates (s-plates) having uniform retardance, which can be easily fabricated by different means such as photoalignment of liquid crystals, metasurfaces etc. Here, exploiting the SU(2) formalism, we establish analytically that any d-plate can be equivalently implemented using a pair of quarter-wave s-plates and a half-wave s-plate. An important advantage of this method is that it gives the flexibility to realize a whole family of distinct d-plates using the same triplet of s-plates. To underline the scope of this method, we propose novel d-plates for spatially tailoring the phase and complex amplitudes of light beams. Towards complex amplitude shaping, we present a generic method for carving out higher-order eigenmodes of light using a d-plate in conjugation with a polarizer. A generalized q-plate-like gadget, for imparting a polarization-dependent phase profile to a scalar light beam, is proposed as a demonstration of phase-polarization interplay. For these two illustrations, the corresponding three-s-plate gadget is constructed, and its functioning is validated with extensive numerical simulations. The main result and its illustrations are generic and agnostic to the way the s-plates are fabricated and we believe they carry the potential to push the current state of the art in interdisciplinary applications involving structured light beams.