Optical Vortex Spin-Orbit Control of Refractive Index in Iron Garnets

TL;DR

This paper demonstrates how orbital angular momentum (OAM) of light can induce nonreciprocal changes in the refractive index of magneto-optical materials, enabling new control mechanisms in photonics and spintronics.

Contribution

It introduces a novel optical phenomenon where OAM states cause state-specific nonreciprocal effects in MO media, expanding understanding of light-matter interactions.

Findings

OAM states induce nonreciprocal refractive index changes.

OAM-dependent optical spin-orbit coupling modifies material response.

The effect enables OAM-selective nonreciprocal photonic devices.

Abstract

The interaction between light's angular momentum (AM) and material systems has unlocked new avenues in structured photonics, including in magneto-optical (MO) materials. While spin angular momentum (SAM) effects in MO systems are well-established, orbital angular momentum (OAM) introduces novel opportunities for new nonreciprocal light-matter interactions. In this study, we demonstrate a unique optical phenomenon where OAM states undergo state-specific nonreciprocal operation within an MO medium, reducing Faraday rotation. This effect arises from transverse momentum transfer into the material, inducing spin-orbit coupling (SOC) at a perturbed electronic transition rate. The resulting OAM-dependent optical SOC modifies the material's refractive index, directly linking structured light and MO response. Our findings extend previous observations of paraxial beams and reveal a deeper fundamental mechanism governing OAM-driven nonreciprocal interactions. These insights pave the way for OAM-selective nonreciprocal photonic devices, chiral optical logic, quantum memory elements, and ultrafast spintronic architectures. This work advances MO integration with structured light for enhanced control over photonic and spintronic systems.