2018
DOI: 10.1103/physrevb.98.045101
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Measuring the temperature of cold many-body quantum systems

Abstract: Precise low-temperature thermometry is a key requirement for virtually any quantum technological application. Unfortunately, as the temperature T decreases, the errors in its estimation diverge very quickly. In this paper, we determine exactly how quickly this may be. We rigorously prove that the "conventional wisdom" of low-T thermometry being exponentially inefficient, is limited to local thermometry on translationally invariant systems with short-range interactions, featuring a non-zero gap above the ground… Show more

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Cited by 77 publications
(127 citation statements)
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“…This linear scaling is in fact expected for translationally invariant gapped systems (see e.g. Appendix A of [31]).…”
Section: Optimal Protocol For Systems With a Well-defined Relaxatsupporting
confidence: 53%
“…This linear scaling is in fact expected for translationally invariant gapped systems (see e.g. Appendix A of [31]).…”
Section: Optimal Protocol For Systems With a Well-defined Relaxatsupporting
confidence: 53%
“…. For further discussions of thermometry for dissipative systems we refer to very recent literature such as in [74]. Figure 7 reveals a similar profile as that for the effective frequencies, thus indicating ballistic transport.…”
Section: Towards Quantum Heat Transfer: Anharmonic Chainssupporting
confidence: 56%
“…1, we show the behaviour of R for different values of the Ohmicity parameter as a function of the dimensionless time and temperature and for the four possible scenarios described in section IV A and IV B. The evaluation of the QSNR can only be performed numerically, through the integration of the decoherence function (14). From Fig.…”
Section: B Separable Qubitsmentioning
confidence: 99%