Entanglement in remote baths induces an emergent nonlocal quantum phase transition with spontaneous symmetry breaking of a collective mode in two spatially separated driven-dissipative resonators.
Generalized master equation for driven quantum oscillators: microscopic origin of nonlinear dissipation and asymmetric resonances
2 Pith papers cite this work. Polarity classification is still indexing.
abstract
Driven nonlinear quantum oscillators are a central platform for quantum technologies, yet their dissipative dynamics are typically described using Lindblad or Caldeira-Leggett master equations derived under assumptions that exclude nonlinearities and driving. Here, we derive a generalized Caldeira-Leggett master equation for driven nonlinear oscillators by retaining the full nonlinear and time-dependent system dynamics in the construction of the dissipator. For position- and momentum-dependent system-bath coupling, the dissipator itself becomes dynamically dressed, generating nonlinear and drive-dependent dissipative channels beyond conventional fixed-dissipator approaches. This produces nonlinear damping together with dissipation-induced corrections to the effective drive. The resulting dissipative dynamics suppress large-amplitude excitations and reduce phase-space fluctuations. For a driven Kerr oscillator, this leads to the suppression of bistability, asymmetric resonance responses, and strongly modified fluctuation distributions. More broadly, our results establish a microscopic framework in which nonlinear dynamics and driving directly reshape the dissipative sector of driven open quantum systems.
fields
quant-ph 2years
2026 2verdicts
UNVERDICTED 2representative citing papers
Demonstrates phase-resolved multichannel quantum escape between coexisting limit cycles in a driven optomechanical resonator via quantum-jump trajectories.
citing papers explorer
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Nonlocal Quantum Phase Transitions
Entanglement in remote baths induces an emergent nonlocal quantum phase transition with spontaneous symmetry breaking of a collective mode in two spatially separated driven-dissipative resonators.
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Phase-resolved multichannel quantum escape between limit cycles
Demonstrates phase-resolved multichannel quantum escape between coexisting limit cycles in a driven optomechanical resonator via quantum-jump trajectories.