Interaction between two Andreev bound state units enhances ergotropy and induces oscillatory charging dynamics in a phase-driven quantum battery.
Cluster Ising quantum batteries can mimic super-extensive charging power
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abstract
Quantum batteries, miniaturized devices able to store and release energy on demand, are promising both because their intrinsic energy and time scales can match those of other quantum technologies and due to the intriguing possibility of achieving super-extensive charging power. While this enhanced scaling is known to appear in several settings, it is generally believed to be forbidden in Jordan-Wigner integrable spin chains charged via quantum-quench protocols. Here, we show that an extended cluster-Ising model, despite belonging to the above category, exhibits super-extensive charging power over wide ranges of system sizes, reaching up to a thousand spins, in proper parameter regimes. This remarkable anomalous scaling is due to a corresponding super-extensive growth of the stored energy, implying that it is limited to a large but finite size of the system and cannot persist in the thermodynamic limit. This phenomenon appears robust against finite-temperature effects.
fields
quant-ph 1years
2026 1verdicts
UNVERDICTED 1representative citing papers
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Interaction-Enhanced Ergotropy in Phase-Driven Andreev Bound State Quantum Batteries
Interaction between two Andreev bound state units enhances ergotropy and induces oscillatory charging dynamics in a phase-driven quantum battery.