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Low-temperature thermometry can be enhanced by strong coupling

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arxiv 1611.10123 v3 pith:ZVSY5YSU submitted 2016-11-30 quant-ph cond-mat.stat-mech

Low-temperature thermometry can be enhanced by strong coupling

classification quant-ph cond-mat.stat-mech
keywords couplingtemperatureprobethermometryenhancedequilibriumestimatesfind
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We consider the problem of estimating the temperature $ T $ of a very cold equilibrium sample. The temperature estimates are drawn from measurements performed on a quantum probe strongly coupled to it. We model this scenario by resorting to the canonical Caldeira-Leggett Hamiltonian and find analytically the exact stationary state of the probe for arbitrary coupling strength. In general, the probe does not reach thermal equilibrium with the sample, due to their non-perturbative interaction. We argue that this is advantageous for low temperature thermometry, as we show in our model that: (i) The thermometric precision at low $ T $ can be significantly enhanced by strengthening the probe-sampling coupling, (ii) the variance of a suitable quadrature of our Brownian thermometer can yield temperature estimates with nearly minimal statistical uncertainty, and (iii) the spectral density of the probe-sample coupling may be engineered to further improve thermometric performance. These observations may find applications in practical nanoscale thermometry at low temperatures---a regime which is particularly relevant to quantum technologies.

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