M. Weideneder scite author profile

M. Weideneder

2Publications

37Citation Statements Received

144Citation Statements Given

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109

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Laboratory of Solid State Physics, Institut Polytechnique de Paris, University of Regensburg

Publications

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Quasiparticle spin resonance and coherence in superconducting aluminium

et al. 2015

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Conventional superconductors were long thought to be spin inert; however, there is now increasing interest in both (the manipulation of) the internal spin structure of the ground-state condensate, as well as recently observed long-lived, spin-polarized excitations (quasiparticles). We demonstrate spin resonance in the quasiparticle population of a mesoscopic superconductor (aluminium) using novel on-chip microwave detection techniques. The spin decoherence time obtained (∼100 ps), and its dependence on the sample thickness are consistent with Elliott–Yafet spin–orbit scattering as the main decoherence mechanism. The striking divergence between the spin coherence time and the previously measured spin imbalance relaxation time (∼10 ns) suggests that the latter is limited instead by inelastic processes. This work stakes out new ground for the nascent field of spin-based electronics with superconductors or superconducting spintronics.

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Evidence for spin-dependent energy transport in a superconductor

Kuzmanović¹,

Wu²,

Weideneder³

et al. 2020

Nat Commun

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In ferromagnetic materials, spin up and down electrons can carry different heat currents. This spin-dependent energy excitation mode ('spin energy mode') occurs only when spin up and down energy distribution functions are different. In superconductors, heat is carried by quasiparticle excitations and the spin energy mode can be excited by spin-polarised current injection. In the presence of a finite Zeeman magnetic field, the spin energy mode surprisingly leads to a charge imbalance (different numbers of hole-and electron-like quasiparticles) at the superconducting gap edge. By performing spin-resolved spectroscopy of the out-ofequilibrium quasiparticle populations in a mescoscopic superconductor, we reveal that their distribution functions are non-Fermi-Dirac. In addition, our spectroscopic technique allows us to observe a charge imbalance, localised in energy to the gap edge and thus unambiguously identify the spin energy mode. Our results agree well with theory and shed light on energy transport in superconducting spintronics.

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M. Weideneder

Quasiparticle spin resonance and coherence in superconducting aluminium

Evidence for spin-dependent energy transport in a superconductor

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