Scalable interconnections for remote exciton systems

TL;DR

This paper presents a scalable platform for interconnecting remote exciton systems using acoustic wave-driven transport and electrostatic gating, enabling efficient manipulation and routing of excitons for photonic information processing.

Contribution

It introduces a novel acoustic wave-based interconnection network combined with electrostatic gates for scalable exciton manipulation and routing.

Findings

Demonstrated long-range transport of dipolar excitons

Implemented an integrated exciton multiplexer

Showed potential for scalable photonic information processing

Abstract

Excitons, quasi-particles consisting of electron-hole pairs bound by the Coulomb interaction, are a potential medium for processing of photonic information in the solid-state. Information processing via excitons requires efficient techniques for the transport and manipulation of these uncharged particles. We introduce here a novel concept for the interconnection of multiple remote exciton systems based on the long-range transport of dipolar excitons by a network of configurable interconnects driven by acoustic wave beams. By combining this network with electrostatic gates, we demonstrate an integrated exciton multiplexer capable of interconnecting, gating and routing exciton systems separated by millimeter distances. The multiplexer provides a scalable platform for the manipulation of exciton fluids with potential applications in information processing.