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Main Authors: Zhang, Rui, Yang, Yang, Ding, Wenkui, Wang, Xiaoguang
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2512.02366
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author Zhang, Rui
Yang, Yang
Ding, Wenkui
Wang, Xiaoguang
author_facet Zhang, Rui
Yang, Yang
Ding, Wenkui
Wang, Xiaoguang
contents This work unifies the equilibrium and non-equilibrium frameworks of quantum metrology within the context of many-body systems. We investigate dynamic sensing schemes to derive an upper bound on the quantum Fisher information for probe states in thermal equilibrium with their environment. We establish that the dynamic quantum Fisher information for a thermal probe state is upper bounded by the degree of non-commutation between the transformed local generator and the Hamiltonian for the thermal state. Furthermore, we show that this upper bound scales as the square of the product of the inverse temperature and the evolution time. In the low-temperature limit, we establish an additional upper bound expressed as the seminorm of the commutator divided by the energy gap. We apply this thermal dynamic sensing scheme to various models, demonstrating that the dynamic quantum Fisher information satisfies the established upper bounds.
format Preprint
id arxiv_https___arxiv_org_abs_2512_02366
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Universal Sensitivity Bound for Thermal Quantum Dynamic Sensing
Zhang, Rui
Yang, Yang
Ding, Wenkui
Wang, Xiaoguang
Quantum Physics
This work unifies the equilibrium and non-equilibrium frameworks of quantum metrology within the context of many-body systems. We investigate dynamic sensing schemes to derive an upper bound on the quantum Fisher information for probe states in thermal equilibrium with their environment. We establish that the dynamic quantum Fisher information for a thermal probe state is upper bounded by the degree of non-commutation between the transformed local generator and the Hamiltonian for the thermal state. Furthermore, we show that this upper bound scales as the square of the product of the inverse temperature and the evolution time. In the low-temperature limit, we establish an additional upper bound expressed as the seminorm of the commutator divided by the energy gap. We apply this thermal dynamic sensing scheme to various models, demonstrating that the dynamic quantum Fisher information satisfies the established upper bounds.
title Universal Sensitivity Bound for Thermal Quantum Dynamic Sensing
topic Quantum Physics
url https://arxiv.org/abs/2512.02366