Effective SU(2) gadget: holonomic walk on higher-order Poincar\'{e} sphere

TL;DR

This paper introduces an effective SU(2) gadget for the higher-order Poincaré sphere using a specific arrangement of q-plates, enabling controlled navigation of structured light with potential applications in advanced optical fields.

Contribution

It demonstrates a novel optical architecture acting as an effective SU(2) gadget for the higher-order Poincaré sphere, based on the concept of an effective waveplate with controlled alignment.

Findings

Controlled navigation on the higher-order Poincaré sphere achieved.

The relative alignment of q-plates' offset angles is key to systematic control.

Potential applications in structured light, singular optics, and quantum communication.

Abstract

In a manner commensurate to the SU(2) gadget for the Poincar\'{e} sphere, which involves a combination of two quarter-wave plates and one half-wave plate regardless of their sequential order, an analogous construct for the higher-order Poincar\'e sphere had long remained elusive. To address this, we recently demonstrated, by modifying Euler-angle parameterization, that an optical gadget consisting of two quarter-wave $q$-plates and one half-wave $q$-plate, each endowed with the same topological charge $q$, operates as a viable SU(2) gadget for the higher-order Poincar\'{e} sphere, contingent upon the fulfillment of the holonomy condition. This work presents the controlled navigation on the higher-order Poincar\'e sphere through the proposed architecture, formulated under the concept of an effective waveplate and thus can be referred to as an effective SU(2) gadget. The notion of an effective waveplate refers to a coaxial arrangement of multiple waveplates that, under specific constraints, can act as a single waveplate. In this gadget, the relative alignment of the offset angles of the constituent $q$-plates emerges as the decisive parameter governing systematic navigation on the higher-order Poincar\'e sphere. This study bear direct relevance to the deterministic control and engineering of structured light, encompassing polarization singularities, vector vortex beams and topological optical fields. Moreover, these results holds potential applications in the contemporary research frontiers in singular optics, spin-orbit photonics and quantum communication.