Nanoscale chiral valley-photon interface through optical spin-orbit coupling

TL;DR

This paper demonstrates room-temperature valley-dependent directional light coupling in a plasmonic nanowire-WS2 system, enabling precise control and detection of valley and spin information at the nanoscale for integrated photonic applications.

Contribution

It introduces a novel on-chip nanophotonic system that achieves high-efficiency valley-dependent optical spin control using plasmonic nanowires and 2D materials.

Findings

Achieved up to 91% optical spin-path locking.

Demonstrated 90% directional coupling efficiency.

Enabled valley pseudospin control at room temperature.

Abstract

The emergence of two-dimensional transition metal chalcogenide materials has sparked an intense activity in valleytronics since their valley information can be directly encoded and detected by using the spin angular momentum of light. For their practical applications such as on-chip valley logic gates and chip-to-chip valley transport, the encoding and processing of valley pseudospin using light should be extended to an integrated, on-chip nanophotonic system. Here, we successfully demonstrate, at room temperature, the valley-dependent directional coupling of light using a plasmonic nanowire-WS2 layers system. Our calculations show that the local transverse spin angular momentum of the mode of the plasmonic nanowire provides robust optical spin-path locking of up to 91 %. Experimentally we demonstrate that valley pseudospin in WS2 is coupled with optical spin of the same handedness and exhibits a high directional coupling efficiency up to 90 % to the plasmonic guided mode. The result opens up new avenues of controlling, detecting and processing valley and spin information with precise optical control at the nanoscale.