Quantum fluid dimers of hyperbolic exciton-polariton condensates

TL;DR

This paper demonstrates an all-optically tunable quantum fluid dimer using hyperbolic exciton-polariton condensates in a photonic crystal waveguide, revealing transitions between evanescent and ballistic coupling regimes with rich interference phenomena.

Contribution

It introduces a novel platform for tuning quantum fluid dimers between evanescent and ballistic coupling modes using photonic crystal structures.

Findings

Transition from evanescent to ballistic coupling by changing dimer angle

Observation of phase-matching and interference patterns in condensates

Spectral features measured and connected to mean field theory

Abstract

Coupled many-body quantum systems give rise to rich emergent physics and abundance of both stationary and dynamical behaviours. Designing platforms with tunable and distinct forms of coupling gives new insight into the collective behaviour of the dimerised quantum systems. Fundamentally, two systems can exchange particles through either forbidden or allowed channels, underpinning evanescent and ballistic coupling mechanisms, respectively. Based on proximity, the former leads to large spectral splitting that defines, for instance, chemical binding energies, whereas the latter pushes for stringent phase-matching and synchronicity between oscillating degrees-of-freedom, analogous to phase-coupled harmonic oscillators, with a significantly smaller impact on the energy landscape. Here, we demonstrate an all-optically tunable evanescent-ballistic quantum fluid dimer based on hyperbolic exciton-polariton condensates in a photonic crystal waveguide. By changing the angle of the polariton dimer relative to the grating, the system transitions from an evanescently-coupled molecule with large mode-splitting to a ballistic condensate dimer with strict phase-matching conditions and rich interference patterns. We directly measure the condensate spectral features and mass flow subject to a saddle dispersion relation, and connect our results to mean field theory. These results showcase the potential of photonic crystals to study condensed matter phenomena lying at the interface between delay-coupled nonlinear oscillators and tight binding physics.