Strongly coupled fermionic probe for nonequilibrium thermometry
Abstract
We characterise the measurement sensitivity, quantified by the Quantum Fisher Information (QFI), of a single-fermionic thermometric probe strongly coupled to the sample of interest, a fermionic bath, at temperature . For nonequilibrium protocols, in which the probe is measured before reaching equilibrium with the sample, we find new behaviour of the measurement sensitivity arising due to non-Markovian dynamics. First, we show that the QFI displays a highly non-monotonic behaviour in time, in contrast to the Markovian case where it grows monotonically until equilibrium, so that non-Markovian revivals can be exploited to reach a higher QFI. Second, the QFI rate is maximised at a finite interrogation time , which we characterize, in contrast to the solution known in the Markovian limit [Quantum 6, 869 (2022)]. Finally, we consider probes make up of few fermions and discuss different collective enhancements in the measurement precision.
Cite
@article{arxiv.2310.14655,
title = {Strongly coupled fermionic probe for nonequilibrium thermometry},
author = {Ricard Ravell Rodríguez and Mohammad Mehboudi and Michał Horodecki and Martí Perarnau-Llobet},
journal= {arXiv preprint arXiv:2310.14655},
year = {2024}
}
Comments
changed some citations. This version is very similar to the one published in NJP