Signatures of Classical Chaos in a Non-Hermitian Quantum System

Quantum mechanics is considered the most fundamental theory for describing nature. Classical mechanics is thought to arise from quantum mechanics in the limit of high quantum numbers. Unlike quantum mechanics, classical mechanics allows for chaotic motion, characterized by sensitivity to initial conditions, a feature ambiguous for translation to quantum systems. Here, we investigate the onset of classical chaos in a non-Hermitian quantum system. We study photons in a microcavity, treated as two-dimensional quantum particles moving in the plane of the resonator. By nanostructuring the resonator's mirrors, we can confine the photons in arbitrary potential landscapes, particularly billiard-like potentials. Non-resonant optical pumping inside of these potentials creates gain in the optical medium. We anticipate that introducing latter will amplify modes with maximum overlap with the gain region, introducing sensitivity to initial conditions, specifically to the pumping spot position. This investigation is expected to shed light on the quantum-to-classical transition in a chaotic system.