Optical spin-to-orbital angular momentum conversion in ultra-thin metasurfaces with arbitrary topological charges

TL;DR

This paper presents a novel ultra-thin metasurface device that efficiently converts the spin of light into arbitrary orbital angular momentum states, enabling rapid manipulation for advanced optical communication and quantum applications.

Contribution

The authors design and experimentally demonstrate a compact plasmonic metasurface capable of converting spin to any OAM value with high efficiency, advancing optical manipulation technologies.

Findings

Achieved OAM values from ±1 to ±25

Conversion efficiency of approximately 8.6%

Device is ultra-thin and integratable for quantum applications

Abstract

Orbital angular momentum associated with the helical phase-front of optical beams provides an unbounded \qo{space} for both classical and quantum communications. Among the different approaches to generate and manipulate orbital angular momentum states of light, coupling between spin and orbital angular momentum allows a faster manipulation of orbital angular momentum states because it depends on manipulating the polarisation state of light, which is simpler and generally faster than manipulating conventional orbital angular momentum generators. In this work, we design and fabricate an ultra-thin spin-to-orbital angular momentum converter, based on plasmonic nano-antennas and operating in the visible wavelength range that is capable of converting spin to an arbitrary value of OAM $\ell$. The nano-antennas are arranged in an array with a well-defined geometry in the transverse plane of the beam, possessing a specific integer or half-integer topological charge $q$. When a circularly polarised light beam traverses this metasurface, the output beam polarisation switches handedness and the OAM changes in value by $\ell = \pm2q\hbar$ per photon. We experimentally demonstrate $\ell$ values ranging from $\pm 1$ to $\pm 25$ with conversion efficiencies of $8.6\pm0.4~\%$. Our ultra-thin devices are integratable and thus suitable for applications in quantum communications, quantum computations and nano-scale sensing.