Multiparameter critical quantum metrology with impurity probes

Mihailescu, George; Bayat, Abolfazl; Campbell, Steve; Mitchell, Andrew K

doi:10.1088/2058-9565/ad438d

Quantum Sci. Technol.

2024

DOI: 10.1088/2058-9565/ad438d

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Multiparameter critical quantum metrology with impurity probes

George Mihailescu,

Abolfazl Bayat,

Steve Campbell

et al.

Abstract: Quantum systems can be used as probes in the context of metrology for enhanced parameter estimation. In particular, the delicacy of critical systems to perturbations can make them ideal sensors. Arguably the simplest realistic probe system is a spin-1/2 impurity, which can be manipulated and measured in-situ when embedded in a fermionic environment. Although entanglement between a single impurity probe and its environment produces nontrivial many-body effects, criticality cannot be leveraged for sensing. Here … Show more

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Cited by 4 publications

References 106 publications

(179 reference statements)

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Critical metrology of minimally accessible anisotropic spin chains

Adani,

Cavazzoni,

Teklu

et al. 2024

Sci Rep

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We address quantum metrology in critical spin chains with anisotropy and Dzyaloshinskii–Moriya (DM) interaction, and show how local and quasi-local measurements may be exploited to characterize global properties of the systems. In particular, we evaluate the classical (magnetization) and quantum Fisher information of the relevant parameters for the density matrix of a single spin and that of a pair of spins ranging from nearest to sixth-nearest neighbors, to the limiting case of very distant spins. Our results allow us to elucidate the role of the different parameters and to individuate the optimal working regimes for the precise characterization of the system, also clarifying the effects of correlations on the estimation precision.

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Critical metrology of minimally accessible anisotropic spin chains

Adani,

Cavazzoni,

Teklu

et al. 2024

Sci Rep

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Dimension matters: precision and incompatibility in multi-parameter quantum estimation models

Candeloro,

Pazhotan,

Paris

2024

Quantum Sci. Technol.

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We study the role of probe dimension in determining the bounds of precision and the level of incompatibility in multi-parameter quantum estimation problems. In particular, we focus on the paradigmatic case of unitary encoding generated by su ( 2 ) and compare precision and incompatibility in the estimation of the same parameters across representations of different dimensions. For two- and three-parameter unitary models, we prove that if the dimension of the probe is smaller than the number of parameters, then simultaneous estimation is not possible (the quantum Fisher matrix is singular). If the dimension is equal to the number of parameters, estimation is possible but the model exhibits maximal (asymptotic) incompatibility. However, for larger dimensions, there is always a state for which the incompatibility vanishes, and the symmetric Cramér-Rao bound is achievable. We also critically examine the performance of the so-called asymptotic incompatibility (AI) in characterising the difference between the Holevo-Cramér-Rao bound and the Symmetric Logarithmic Derivative one, showing that the AI measure alone may fail to adequately quantify this gap. Assessing the determinant of the Quantum Fisher Information Matrix is crucial for a precise characterisation of the model’s nature. Nonetheless, the AI measure still plays a relevant role since it encapsulates the non-classicality of the model in one scalar quantity rather than in a matrix form (i.e. the Uhlmann curvature).

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Temperature-enhanced critical quantum metrology

Ostermann,

Gietka

2024

Phys. Rev. A

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Multiparameter critical quantum metrology with impurity probes

Cited by 4 publications

References 106 publications

Critical metrology of minimally accessible anisotropic spin chains

Critical metrology of minimally accessible anisotropic spin chains

Dimension matters: precision and incompatibility in multi-parameter quantum estimation models

Temperature-enhanced critical quantum metrology

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