Related papers: Weakly invasive metrology: quantum advantage and physical implementations

Weakly invasive metrology: quantum advantage and physical implementations

URL: http://arxiv.org/abs/2006.12114v4
Date: Fri, 23 Apr 2021 13:09:22 GMT
Title: Weakly invasive metrology: quantum advantage and physical implementations
Authors: M. Perarnau-Llobet, D. Malz, J. I. Cirac
Abstract summary: We show that arbitrarily intense coherent states can obtain information at a rate that scales at most linearly with $N_rm abs$ and $T$. We discuss an implementation in cavity QED, where Fock states are both prepared and measured by coupling atomic ensembles to the cavities.
Score: 0.0
License: http://creativecommons.org/licenses/by/4.0/
Abstract: We consider the estimation of a Hamiltonian parameter of a set of highly photosensitive samples, which are damaged after a few photons $N_{\rm abs}$ are absorbed, for a total time $T$. The samples are modelled as a two mode photonic system, where photons simultaneously acquire information on the unknown parameter and are absorbed at a fixed rate. We show that arbitrarily intense coherent states can obtain information at a rate that scales at most linearly with $N_{\rm abs}$ and $T$, whereas quantum states with finite intensity can overcome this bound. We characterise the quantum advantage as a function of $N_{\rm abs}$ and $T$, as well as its robustness to imperfections (non-ideal detectors, finite preparation and measurement rates for quantum photonic states). We discuss an implementation in cavity QED, where Fock states are both prepared and measured by coupling atomic ensembles to the cavities. We show that superradiance, arising due to a collective coupling between the cavities and the atoms, can be exploited for improving the speed and efficiency of the measurement.

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