Direct measurement of the quantum geometric tensor in a two-dimensional continuous medium

TL;DR

This paper demonstrates the first direct measurement of both Berry curvature and quantum metric in a two-dimensional continuous medium using exciton-polaritons in a high-finesse microcavity, revealing intrinsic photonic chirality and topological properties.

Contribution

It introduces a novel experimental technique to directly measure quantum geometric tensors in a continuous medium, advancing topological photonics research.

Findings

Measured Berry curvature and quantum metric in a 2D microcavity

Revealed intrinsic chirality of photonic modes

Extended measurement technique to artificial lattices

Abstract

Topological Physics relies on the specific structure of the eigenstates of Hamiltonians. Their geometry is encoded in the quantum geometric tensor containing both the celebrated Berry curvature, crucial for topological matter, and the quantum metric. The latter is at the heart of a growing number of physical phenomena such as superfluidity in flat bands, orbital magnetic susceptibility, exciton Lamb shift, and non-adiabatic corrections to the anomalous Hall effect. Here, we report the first direct measurement of both Berry curvature and quantum metric in a two-dimensional continuous medium. The studied platform is a planar microcavity of extremely high finesse, in the strong coupling regime. It hosts mixed exciton-photon modes (exciton-polaritons) subject to photonic spin-orbit-coupling which makes emerge Dirac cones and exciton Zeeman splitting breaking time-reversal symmetry. The monopolar and half-skyrmion pseudospin textures are measured by polarisation-resolved photoluminescence. The associated quantum geometry of the bands is straightforwardly extracted from these measurements. Our results unveil the intrinsic chirality of photonic modes which is at the basis of topological photonics. This technique can be extended to measure Bloch band geometries in artificial lattices. The use of exciton-polaritons (interacting photons) opens wide perspectives for future studies of quantum fluid physics in topological systems.