Strong system-bath coupling induces a bright-dark structure in the effective coupling operator, producing a hierarchy of population relaxation timescales via spectral localization bounds on the Liouvillian in the reaction-coordinate polaron framework.
Reservoir-mediated spin entanglement in the mean-force Gibbs state
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abstract
Two qubits strongly coupled to a common bosonic reservoir can become entangled with each other, despite having no direct interaction. In equilibrium, such coupling-induced coherences can be described by the mean-force Gibbs state. Here we derive approximate, analytic expressions for the two-qubit mean-force Gibbs state, and use these to characterize equilibrium qubit-qubit entanglement mediated by a thermal reservoir. Entanglement, which is highest at lowest temperatures, is a non-monotonic function of the system-reservoir coupling strength. Moreover, we find that broadening the reservoir spectral density beyond a single mode, as is realistic for typical baths, can enhance the qubit entanglement. Our results provide a comprehensive understanding of reservoir-mediated two-qubit entanglement in thermal equilibrium and provide a benchmark to compare with numerical methods, as well as demonstrating the utility of strong system-reservoir coupling as a resource.
fields
quant-ph 1years
2026 1verdicts
UNVERDICTED 1representative citing papers
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Hierarchical separation of relaxation timescales from spectral localization bounds
Strong system-bath coupling induces a bright-dark structure in the effective coupling operator, producing a hierarchy of population relaxation timescales via spectral localization bounds on the Liouvillian in the reaction-coordinate polaron framework.