Reentrant proximity-induced superconductivity for GeTe semimetal

We experimentally investigate charge transport in In-GeTe and In-GeTe-In proximity devices, which are formed as junctions between superconducting indium leads and thick single crystal flakes of $\alpha$-GeTe topological semimetal. We observe nonmonotonic effects of the applied external magnetic fi...

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Veröffentlicht in:	arXiv.org 2023-04
Hauptverfasser:	Esin, V D, D Yu Kazmin, Barash, Yu S, Timonina, A V, Kolesnikov, N N, Deviatov, E V
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Sprache:	eng
Schlagworte:	Charge transport Electrons Fields (mathematics) Heterostructures Josephson junctions Magnetic fields Physics - Mesoscale and Nanoscale Physics Physics - Superconductivity Polarization (spin alignment) Single crystals Spin-orbit interactions Superconductivity Topology
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creator	Esin, V D D Yu Kazmin Barash, Yu S Timonina, A V Kolesnikov, N N Deviatov, E V
description	We experimentally investigate charge transport in In-GeTe and In-GeTe-In proximity devices, which are formed as junctions between superconducting indium leads and thick single crystal flakes of $\alpha$-GeTe topological semimetal. We observe nonmonotonic effects of the applied external magnetic field, including reentrant superconductivity in In-GeTe-In Josephson junctions: supercurrent reappears at some finite magnetic field. For a single In-GeTe Andreev junction, the superconducting gap is partially suppressed in zero magnetic field, while the gap is increased nearly to the bulk value for some finite field before its full suppression. We discuss possible reasons for the results obtained, taking into account spin polarization of Fermi arc surface states in topological semimetal $\alpha$-GeTe with a strong spin-orbit coupling. In particular, the zero-field surface state spin polarization partially suppresses the superconductivity, while it is recovered due to the modified spin-split surface state configuration in finite fields. As an alternative possible scenario, the transition into the Fulde-Ferrell-Larkin-Ovchinnikov state is discussed. However, the role of strong spin-orbit coupling in forming the nonmonotonic behavior has not been analyzed for heterostructures in the Fulde-Ferrell-Larkin-Ovchinnikov state, which is crucial for junctions involving GeTe topological semimetal.
doi_str_mv	10.48550/arxiv.2304.05971
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We observe nonmonotonic effects of the applied external magnetic field, including reentrant superconductivity in In-GeTe-In Josephson junctions: supercurrent reappears at some finite magnetic field. For a single In-GeTe Andreev junction, the superconducting gap is partially suppressed in zero magnetic field, while the gap is increased nearly to the bulk value for some finite field before its full suppression. We discuss possible reasons for the results obtained, taking into account spin polarization of Fermi arc surface states in topological semimetal $\alpha$-GeTe with a strong spin-orbit coupling. In particular, the zero-field surface state spin polarization partially suppresses the superconductivity, while it is recovered due to the modified spin-split surface state configuration in finite fields. As an alternative possible scenario, the transition into the Fulde-Ferrell-Larkin-Ovchinnikov state is discussed. 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subjects	Charge transport Electrons Fields (mathematics) Heterostructures Josephson junctions Magnetic fields Physics - Mesoscale and Nanoscale Physics Physics - Superconductivity Polarization (spin alignment) Single crystals Spin-orbit interactions Superconductivity Topology
title	Reentrant proximity-induced superconductivity for GeTe semimetal
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