Microscopic calculations indicate that altermagnetic Josephson junctions in transmon qubits yield decoherence protection and high anharmonicity, with strain proposed to tune gate speeds.
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3 Pith papers cite this work. Polarity classification is still indexing.
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UNVERDICTED 3representative citing papers
Derives a refraction law for vortices at tilted SN interfaces, confirmed by proximity-effect simulations that also reveal low-mass trapping and viscosity-driven displacements under transport current.
Gate-biased near-IR illumination alters oxide-semiconductor trapped charge to individually tune Si/SiGe quantum dot operating voltages to uniformity while leaving charge noise unchanged.
citing papers explorer
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Enhanced qubit performance by integrating altermagnets into superconducting qubit designs
Microscopic calculations indicate that altermagnetic Josephson junctions in transmon qubits yield decoherence protection and high anharmonicity, with strain proposed to tune gate speeds.
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Vortex Refraction at Tilted Superconductor-Normal Metal Interfaces
Derives a refraction law for vortices at tilted SN interfaces, confirmed by proximity-effect simulations that also reveal low-mass trapping and viscosity-driven displacements under transport current.
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Individually tunable Si/SiGe quantum dot operating voltages via gate-biased illumination
Gate-biased near-IR illumination alters oxide-semiconductor trapped charge to individually tune Si/SiGe quantum dot operating voltages to uniformity while leaving charge noise unchanged.