Related papers: Exact steady state of quantum van der Pol oscillator: critical phenomena and enhanced metrology

Exact steady state of quantum van der Pol oscillator: critical phenomena and enhanced metrology

URL: http://arxiv.org/abs/2412.03354v1
Date: Wed, 04 Dec 2024 14:39:02 GMT
Title: Exact steady state of quantum van der Pol oscillator: critical phenomena and enhanced metrology
Authors: Yaohua Li, Xuanchen Zhang, Yong-Chun Liu,
Abstract summary: We show the threshold corresponds to a dissipative phase transition with abrupt changes of steady-state properties. The critical behaviors and finite-size effects are investigated through the analytical steady state.
Score: 0.29260385019352086
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Abstract: Quantum criticality of open many-body systems has attracted lots of interest for emergent phenomena and universality. Here we present the exact steady state of the quantum van der Pol oscillator using the complex $P$-representation. We show the threshold corresponds to a dissipative phase transition with abrupt changes of steady-state properties and enhanced metrology. The critical behaviors and finite-size effects are investigated through the analytical steady state. Moreover, we obtain divergent quantum Fisher information (QFI) in the thermodynamic limit both at the critical point and in the time crystal phase, but only the QFI at the critical point approaches the Heisenberg limit. We further prove that the steady-state photon number is the optimized estimated observable with the largest signal-to-noise ratio. We show that the Heisenberg-limited metrology originates from the enhancement of both the variance and changing rate of the photon number. Our work reveals the underlying relation between the time crystal, dissipative phase transition, and enhanced metrology.

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