Programmable energy-selective local reservoirs stabilize entangled single-excitation states in coupled superconducting qubits with fidelity up to 90.8% via parametric driving to readout resonators.
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Thermodynamic recycling of algorithmic failure branches enables information erasure with heat dissipation below the Landauer limit on a quantum processor.
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Entangling Superconducting Qubits via Energy-Selective Local Reservoirs
Programmable energy-selective local reservoirs stabilize entangled single-excitation states in coupled superconducting qubits with fidelity up to 90.8% via parametric driving to readout resonators.
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Thermodynamic Recycling of Algorithmic Failure Branches: Quantum-Computer Demonstration with Quantum Error Correction
Thermodynamic recycling of algorithmic failure branches enables information erasure with heat dissipation below the Landauer limit on a quantum processor.