Time-scale entanglement, quantified by bond dimensions in quantics tensor trains of n-particle correlators, is enhanced near phase transitions and scale-invariant at quantum critical points across multiple models.
GB further acknowledges support through the SFB Q- M&S project of the FWF, DOI 10.55776/F86
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Non-stabilizerness of the Hubbard dimer is computed with robustness of magic and stabilizer Rényi entropy, revealing it as a resource distinct from fermionic non-Gaussianity and superselected entanglement.
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.
citing papers explorer
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Diagnosing phase transitions through time-scale entanglement
Time-scale entanglement, quantified by bond dimensions in quantics tensor trains of n-particle correlators, is enhanced near phase transitions and scale-invariant at quantum critical points across multiple models.
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Quantum magic of strongly correlated fermions $-$ the Hubbard dimer
Non-stabilizerness of the Hubbard dimer is computed with robustness of magic and stabilizer Rényi entropy, revealing it as a resource distinct from fermionic non-Gaussianity and superselected entanglement.
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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.