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arxiv: 1904.07560 · v1 · pith:O35QH7UG · submitted 2019-04-16 · cond-mat.stat-mech · cond-mat.quant-gas· math-ph· math.MP· quant-ph

Partition of energy for a dissipative quantum oscillator

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classification cond-mat.stat-mech cond-mat.quant-gasmath-phmath.MPquant-ph
keywords langlerangleenergymathcalmeanomegaoscillatorquantum
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We reveal a new face of the old clich\'ed system: a dissipative quantum harmonic oscillator. We formulate and study a quantum counterpart of the energy equipartition theorem satisfied for classical systems.Both mean kinetic energy $E_k$ and mean potential energy $E_p$ of the oscillator are expressed as $E_k = \langle \mathcal E_k \rangle$ and $E_p = \langle \mathcal E_p \rangle$, where $\langle \mathcal E_k \rangle$ and $ \langle \mathcal E_p \rangle$ are mean kinetic and potential energies per one degree of freedom of the thermostat which consists of harmonic oscillators too. The symbol $\langle ...\rangle$ denotes two-fold averaging: (i) over the Gibbs canonical state for the thermostat and (ii) over thermostat oscillators frequencies $\omega$ which contribute to $E_k$ and $E_p$ according to the probability distribution $\mathbb{P}_k(\omega)$ and $\mathbb{P}_p(\omega)$, respectively. The role of the system-thermostat coupling strength and the memory time is analysed for the exponentially decaying memory function (Drude dissipation mechanism) and the algebraically decaying damping kernel.

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