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Main Authors: Jimenez-Romero, A. A., Rojas, F.
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2605.03248
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author Jimenez-Romero, A. A.
Rojas, F.
author_facet Jimenez-Romero, A. A.
Rojas, F.
contents We develop a general perturbation theory for the local quantum uncertainty (LQU), a discord-type quantifier of nonclassicality based on the Wigner-Yanase skew information. Starting from a perturbed density matrix $ρ= ρ_0 + ερ_1$,we derive an explicit first-order expansion of $ρ^{1/2}$ using an integral representation based on the gamma function, and reduce the LQU optimization to the diagonalization of a $(d_1^2-1) \times (d_1^2-1)$ matrix $w = w^0 + w^1$ defined in terms of the $\mathrm{SU}(d_1)$ generators. The framework is valid for composite systems of arbitrary dimension $d_1 \times d_2$ and provides a direct computational route to the LQU from the spectral decomposition of the unperturbed state. We further specialize the theory to the quantum linear response regime, where the perturbation is generated by a time-dependent external field, and $w^1$ acquires explicit dependence on the driving frequency $ω$, the eigenstates and occupation probabilities of the equilibrium Hamiltonian $H_0$, and the matrix elements of the coupling operator $\hat{A}$. As an illustration, we apply the formalism to the isotropic Heisenberg model of two coupled spins driven by a local periodic magnetic field, obtaining closed-form expressions for the LQU as a function of temperature $T$ and frequency $ω$. Comparison with the concurrence shows that above the entanglement critical temperature $T_c$, the external field induces a resonantly enhanced quantum discord without generating entanglement, demonstrating that frequency acts as a tunable modulator of nonclassicality -- an effect of purely quantum-discord type inaccessible to entanglement-based quantifiers.
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publishDate 2026
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spellingShingle General perturbation theory for local quantum uncertainty and its formulation in the linear-response regime
Jimenez-Romero, A. A.
Rojas, F.
Quantum Physics
We develop a general perturbation theory for the local quantum uncertainty (LQU), a discord-type quantifier of nonclassicality based on the Wigner-Yanase skew information. Starting from a perturbed density matrix $ρ= ρ_0 + ερ_1$,we derive an explicit first-order expansion of $ρ^{1/2}$ using an integral representation based on the gamma function, and reduce the LQU optimization to the diagonalization of a $(d_1^2-1) \times (d_1^2-1)$ matrix $w = w^0 + w^1$ defined in terms of the $\mathrm{SU}(d_1)$ generators. The framework is valid for composite systems of arbitrary dimension $d_1 \times d_2$ and provides a direct computational route to the LQU from the spectral decomposition of the unperturbed state. We further specialize the theory to the quantum linear response regime, where the perturbation is generated by a time-dependent external field, and $w^1$ acquires explicit dependence on the driving frequency $ω$, the eigenstates and occupation probabilities of the equilibrium Hamiltonian $H_0$, and the matrix elements of the coupling operator $\hat{A}$. As an illustration, we apply the formalism to the isotropic Heisenberg model of two coupled spins driven by a local periodic magnetic field, obtaining closed-form expressions for the LQU as a function of temperature $T$ and frequency $ω$. Comparison with the concurrence shows that above the entanglement critical temperature $T_c$, the external field induces a resonantly enhanced quantum discord without generating entanglement, demonstrating that frequency acts as a tunable modulator of nonclassicality -- an effect of purely quantum-discord type inaccessible to entanglement-based quantifiers.
title General perturbation theory for local quantum uncertainty and its formulation in the linear-response regime
topic Quantum Physics
url https://arxiv.org/abs/2605.03248