Dissipative coupling induced phonon lasing with anti-parity-time symmetry

TL;DR

This paper introduces a novel phonon lasing mechanism based on dissipative coupling in an anti-PT symmetric optomechanical system, demonstrating non-Hermitian phase transition and self-sustained phonon oscillations.

Contribution

It presents the first demonstration of phonon lasing driven by dissipative coupling and anti-PT symmetry, expanding the understanding of non-Hermitian physics in phononic systems.

Findings

Observation of level attraction and damping repulsion signatures

Phonon modes exhibit self-sustained oscillations beyond a critical interaction strength

Measurement of second-order phonon correlations reveals coherence in the lasing regime

Abstract

Phonon lasers, as the counterpart of photonic lasers, have been intensively studied in a large variety of systems, however, (all) most of them are based on the directly coherent pumping. Intuitively, dissipation is an unfavorable factor for gain in a laser. Here we demonstrate a novel mechanism of phonon lasing from the dissipative coupling in a multimode optomechanical system. By precisely engineering the dissipations of two membranes and tuning the intensity modulation of the cavity light, the two-membrane-in-the-middle system shows anti-parity-time (anti-PT) symmetry and the cavity mediated interaction between two nanomechanical resonators becomes purely dissipative. The level attraction and damping repulsion are clearly exhibited as the signature of dissipative coupling. After the exceptional point, a non-Hermitian phase transition, where eigenvalues and the corresponding eigenmodes coalesce, two phonon modes are simultaneously excited into the self-sustained oscillation regime by increasing the interaction strength over a critical value (threshold). In distinct contrast to conventional phonon lasers, the measurement of the second-order phonon correlation reveals the oscillatory and biexponential phases in the nonlasing regime as well as the coherence phase in the lasing regime. Our study provides a new method to study phonon lasers in a non-Hermitian open system and could be applied to a wide range of disciplines, including optics, acoustics, and quantum many-body physics.