Fundamental Limits in Bayesian Thermometry and Attainability via Adaptive Strategies

Mohammad Mehboudi; Mathias R. Jørgensen; Stella Seah; Jonatan B. Brask; Jan Kołodyński; Martí Perarnau-Llobet

doi:10.1103/PhysRevLett.128.130502

Fundamental Limits in Bayesian Thermometry and Attainability via Adaptive Strategies

Mohammad Mehboudi, Mathias R. Jørgensen, Stella Seah, Jonatan B. Brask, Jan Kołodyński, Martí Perarnau-Llobet

Departament de Física

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We investigate the limits of thermometry using quantum probes at thermal equilibrium within the Bayesian approach. We consider the possibility of engineering interactions between the probes in order to enhance their sensitivity, as well as feedback during the measurement process, i.e., adaptive protocols. On the one hand, we obtain an ultimate bound on thermometry precision in the Bayesian setting, valid for arbitrary interactions and measurement schemes, which lower bounds the error with a quadratic (Heisenberg-like) scaling with the number of probes. We develop a simple adaptive strategy that can saturate this limit. On the other hand, we derive a no-go theorem for nonadaptive protocols that does not allow for better than linear (shot-noise-like) scaling even if one has unlimited control over the probes, namely, access to arbitrary many-body interactions.

Idioma original	Anglès
Número d’article	130502
Revista	Physical review letters
Volum	128
DOIs	https://doi.org/10.1103/PhysRevLett.128.130502
Estat de la publicació	Publicada - 1 d’abr. 2022

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title = "Fundamental Limits in Bayesian Thermometry and Attainability via Adaptive Strategies",

abstract = "We investigate the limits of thermometry using quantum probes at thermal equilibrium within the Bayesian approach. We consider the possibility of engineering interactions between the probes in order to enhance their sensitivity, as well as feedback during the measurement process, i.e., adaptive protocols. On the one hand, we obtain an ultimate bound on thermometry precision in the Bayesian setting, valid for arbitrary interactions and measurement schemes, which lower bounds the error with a quadratic (Heisenberg-like) scaling with the number of probes. We develop a simple adaptive strategy that can saturate this limit. On the other hand, we derive a no-go theorem for nonadaptive protocols that does not allow for better than linear (shot-noise-like) scaling even if one has unlimited control over the probes, namely, access to arbitrary many-body interactions.",

author = "Mohammad Mehboudi and J{\o}rgensen, {Mathias R.} and Stella Seah and Brask, {Jonatan B.} and Jan Ko{\l}ody{\'n}ski and Mart{\'i} Perarnau-Llobet",

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AU - Mehboudi, Mohammad

AU - Jørgensen, Mathias R.

AU - Seah, Stella

AU - Brask, Jonatan B.

AU - Kołodyński, Jan

AU - Perarnau-Llobet, Martí

PY - 2022/4/1

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N2 - We investigate the limits of thermometry using quantum probes at thermal equilibrium within the Bayesian approach. We consider the possibility of engineering interactions between the probes in order to enhance their sensitivity, as well as feedback during the measurement process, i.e., adaptive protocols. On the one hand, we obtain an ultimate bound on thermometry precision in the Bayesian setting, valid for arbitrary interactions and measurement schemes, which lower bounds the error with a quadratic (Heisenberg-like) scaling with the number of probes. We develop a simple adaptive strategy that can saturate this limit. On the other hand, we derive a no-go theorem for nonadaptive protocols that does not allow for better than linear (shot-noise-like) scaling even if one has unlimited control over the probes, namely, access to arbitrary many-body interactions.

AB - We investigate the limits of thermometry using quantum probes at thermal equilibrium within the Bayesian approach. We consider the possibility of engineering interactions between the probes in order to enhance their sensitivity, as well as feedback during the measurement process, i.e., adaptive protocols. On the one hand, we obtain an ultimate bound on thermometry precision in the Bayesian setting, valid for arbitrary interactions and measurement schemes, which lower bounds the error with a quadratic (Heisenberg-like) scaling with the number of probes. We develop a simple adaptive strategy that can saturate this limit. On the other hand, we derive a no-go theorem for nonadaptive protocols that does not allow for better than linear (shot-noise-like) scaling even if one has unlimited control over the probes, namely, access to arbitrary many-body interactions.

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DO - 10.1103/PhysRevLett.128.130502

M3 - Article

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VL - 128

JO - Physical review letters

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M1 - 130502

ER -

Fundamental Limits in Bayesian Thermometry and Attainability via Adaptive Strategies

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