Two-photon parametric amplification in a superconducting circuit exponentially strengthens cavity-qubit coupling, enabling faster charging and decoherence-resistant energy storage in a quantum battery.
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Tuning charger frequency to resonance in a 1D bosonic quantum battery achieves perfect energy transfer, with many-body effects and attractive interactions enhancing charging power and efficiency over single-particle cases.
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Quantum battery optimized by parametric amplification
Two-photon parametric amplification in a superconducting circuit exponentially strengthens cavity-qubit coupling, enabling faster charging and decoherence-resistant energy storage in a quantum battery.
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Enhancing ultracold atomic batteries using tunable interactions
Tuning charger frequency to resonance in a 1D bosonic quantum battery achieves perfect energy transfer, with many-body effects and attractive interactions enhancing charging power and efficiency over single-particle cases.