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Observation of a non-Hermitian phase transition in an optical quantum gas

Fahri Emre Öztürk, Tim Lappe, Göran Hellmann, Julian Schmitt, Jan Klaers, Frank Vewinger, Johann Kroha, Martin Weitz

2021Science85 citationsDOIOpen Access PDF

Abstract

Quantum gases of light, such as photon or polariton condensates in optical microcavities, are collective quantum systems enabling a tailoring of dissipation from, for example, cavity loss. This characteristic makes them a tool to study dissipative phases, an emerging subject in quantum many-body physics. We experimentally demonstrate a non-Hermitian phase transition of a photon Bose-Einstein condensate to a dissipative phase characterized by a biexponential decay of the condensate's second-order coherence. The phase transition occurs because of the emergence of an exceptional point in the quantum gas. Although Bose-Einstein condensation is usually connected to lasing by a smooth crossover, the observed phase transition separates the biexponential phase from both lasing and an intermediate, oscillatory condensate regime. Our approach can be used to study a wide class of dissipative quantum phases in topological or lattice systems.

Topics & Concepts

Quantum phase transitionDissipative systemPhysicsLasing thresholdQuantum phasesQuantumPhase transitionQuantum critical pointPhotonPolaritonCondensed matter physicsDissipationOptical cavityQuantum point contactPhase (matter)Quantum opticsCavity quantum electrodynamicsQuantum mechanicsLattice (music)Optical latticeQuantum dotMolecular physicsQuantum fluctuationQuantum dynamicsQuantum dissipationCritical point (mathematics)Atomic physicsTransition pointQuantum fluidQuantum technologyQuantum Mechanics and Non-Hermitian PhysicsMechanical and Optical ResonatorsCold Atom Physics and Bose-Einstein Condensates
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