Tight Quantum Speed Limit for Ergotropy Charging in the N-Qubit Dicke Battery

Anass Jad; Abderrahim El Allati

arXiv:2603.10415·quant-ph·March 18, 2026

Tight Quantum Speed Limit for Ergotropy Charging in the N-Qubit Dicke Battery

Anass Jad, Abderrahim El Allati

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Abstract

We derive and analytically prove a tight quantum speed limit (QSL) for ergotropy charging in the $N$ -qubit Dicke quantum battery: the first-passage time to normalised ergotropy $ϵ$ satisfies $τ^{*} (ϵ) \geq N ϵ / (2 λ \overset{n}{ˉ})$ , where $λ$ is the coupling and $\overset{n}{ˉ}$ is the mean charger photon number. The bound follows from an exact perturbative identity $ϵ (t) = A λ^{2} \overset{n}{ˉ} t^{2} + O ((λ t)^{4})$ , where $A = 4/ N$ is the short-time ergotropy coefficient, combined with a global upper bound proved analytically for all $N$ . The composite parameter $Γ_{N} = 2 λ \overset{n}{ˉ} / N$ is the unique figure of merit for charging speed; all protocols collapse onto $Γ_{N} τ^{*} \geq ϵ$ , with the bound saturated to within 1% at small $ϵ$ .

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TopicsAdvanced Thermodynamics and Statistical Mechanics · Quantum many-body systems · Quantum-Dot Cellular Automata