Gaussian quantum metrology in a dissipative environment

AbstractIt has long been recognized that emission of radiation from atoms is not an intrinsic property of individual atoms themselves, but it is largely affected by the characteristics of the photonic environment and by the collective interaction among the atoms. A general belief is that preventing full decay and/or decoherence requires the existence of dark states, i.e., dressed light-atom states that do not decay despite the dissipative environment. Here, we show that, contrary to such a common wisdom, decoherence suppression can be intermittently achieved on a limited time scale, without the need for any dark state, when the atom is coupled to a chiral ring environment, leading to a highly non-exponential staircase decay. This effect, that we refer to as intermittent decoherence blockade, arises from periodic destructive interference between light emitted in the present and light emitted in the past, i.e., from delayed coherent quantum feedback.

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Multiparameter quantum metrology with postselection measurements

Journal of Mathematical Physics ◽

10.1063/5.0024555 ◽

2021 ◽

Vol 62 (1) ◽

pp. 012102

Author(s):

Le Bin Ho ◽

Yasushi Kondo

Keyword(s):

Quantum Metrology

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A variational toolbox for quantum multi-parameter estimation

npj Quantum Information ◽

10.1038/s41534-021-00425-y ◽

2021 ◽

Vol 7 (1) ◽

Author(s):

Johannes Jakob Meyer ◽

Johannes Borregaard ◽

Jens Eisert

Keyword(s):

Parameter Estimation ◽

Information Science ◽

Quantum Algorithms ◽

Continuous Variable ◽

General Interest ◽

Quantum Metrology ◽

Estimation Problems ◽

General Parameter ◽

Quantum Technology ◽

Aided Design

AbstractWith an ever-expanding ecosystem of noisy and intermediate-scale quantum devices, exploring their possible applications is a rapidly growing field of quantum information science. In this work, we demonstrate that variational quantum algorithms feasible on such devices address a challenge central to the field of quantum metrology: The identification of near-optimal probes and measurement operators for noisy multi-parameter estimation problems. We first introduce a general framework that allows for sequential updates of variational parameters to improve probe states and measurements and is widely applicable to both discrete and continuous-variable settings. We then demonstrate the practical functioning of the approach through numerical simulations, showcasing how tailored probes and measurements improve over standard methods in the noisy regime. Along the way, we prove the validity of a general parameter-shift rule for noisy evolutions, expected to be of general interest in variational quantum algorithms. In our approach, we advocate the mindset of quantum-aided design, exploiting quantum technology to learn close to optimal, experimentally feasible quantum metrology protocols.

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