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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Numerical simulations predict that tensile or unstrained germanium heterostructures yield spin splittings over 100 times larger than compressive cases, enabling GHz Andreev spin qubits with 100 ns all-electric gates.
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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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Strain engineering of Andreev spin qubits in Germanium
Numerical simulations predict that tensile or unstrained germanium heterostructures yield spin splittings over 100 times larger than compressive cases, enabling GHz Andreev spin qubits with 100 ns all-electric gates.