Granular aluminum induces a hard, magnetically resilient superconducting gap of 305 μeV in germanium, allowing Zeeman splitting of YSR states beyond 50 μeV and g-tensor tunability for hole-based hybrid quantum devices.
Glezer Moshe, E
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Cryogenic growth at 6 K increases structural disorder in aluminum films, enhancing superconductivity with higher Tc and critical field, shifting optical color to yellow, and raising kinetic inductance while microwave loss remains TLS-dominated.
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Granular aluminum induced superconductivity in germanium for hole spin-based hybrid devices
Granular aluminum induces a hard, magnetically resilient superconducting gap of 305 μeV in germanium, allowing Zeeman splitting of YSR states beyond 50 μeV and g-tensor tunability for hole-based hybrid quantum devices.
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Cryogenic growth of aluminum: structural morphology, optical properties, superconductivity and microwave dielectric loss
Cryogenic growth at 6 K increases structural disorder in aluminum films, enhancing superconductivity with higher Tc and critical field, shifting optical color to yellow, and raising kinetic inductance while microwave loss remains TLS-dominated.