Direct Measurement of a Non-Hermitian Topological Invariant in a Hybrid Light-Matter System


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Topology is central to understanding and engineering materials that display robust physical phenomena immune to imperfections. The topological character of a material is quantified by topological invariants that simplify the classification of topological phases. In energy-conserving systems, the topological invariants, e.g., the Chern number, are determined by the winding of the eigenstates in momentum (wavevector) space, which have been experimentally measured in ultracold atoms, microwaves, and photonic systems. Recently, new topological phenomena have been theoretically uncovered in dissipative, non-Hermitian systems. A novel, non-Hermitian topological invariant, yet to be observed in experiments, is predicted to emerge from the winding of the complex eigenvalues in momentum space. Here, we directly measure the non-Hermitian topological invariant arising from spectral degeneracies (exceptional points) in the momentum space of exciton polaritons. These hybrid light-matter quasiparticles are formed by photons strongly coupled to electron-hole pairs (excitons) in a halide perovskite semiconductor microcavity at room temperature. By performing momentum-resolved photoluminescence spectroscopy of exciton polaritons, we map out both the real (energy) and imaginary (linewidth) parts of the exciton-polariton eigenvalues near the exceptional point, and extract a new topological invariant - fractional spectral winding. Our work represents an essential step towards realisation of non-Hermitian topological phases in a solid-state system.

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