Abstract
There is much current interest in combining superconductivity and spin–orbit coupling in order to induce the topological superconductor phase and associated Majorana-like quasiparticles which hold great promise towards fault-tolerant quantum computing. Experimentally these effects have been combined by the proximity-coupling of super-conducting leads and high spin–orbit materials such as InSb and InAs, or by controlled Cu-doping of topological insu-lators such as Bi2Se3. However, for practical purposes, a single-phase material which intrinsically displays both these effects is highly desirable. Here we demonstrate coexisting superconducting correlations and spin–orbit coupling in molecular-beam-epitaxy-grown thin films of GeTe. The former is evidenced by a precipitous low-temperature drop in the electrical resistivity which is quelled by a magnetic field, and the latter manifests as a weak antilocalisation (WAL) cusp in the magnetotransport. Our studies reveal several other intriguing features such as the presence of two-dimensional rather than bulk transport channels below 2 K, possible signatures of topological superconductivity, and unexpected hysteresis in the magnetotransport. Our work demonstrates GeTe to be a potential host of topological SC and Majorana-like excitations, and to be a versatile platform to develop quantum information device architectures. (© 2016 The Authors. Phys. Status Solidi RRL published by WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim)
Highlights
The confluence of superconductivity and spin–orbit (SO) interactions in the solid-state has presented several opportunities towards fault-tolerant quantum information processing
Our work demonstrates GeTe to be a potential host of topological SC and Majoranalike excitations, and to be a versatile platform to develop quantum information device architectures
We show that the lowtemperature transport characteristics of GeTe reveal both a precipitous drop in resistivity, indicating the onset of superconductivity, as well as unambiguous weak anti-localisation (WAL) signatures due to the strong SO field
Summary
The confluence of superconductivity and spin–orbit (SO) interactions in the solid-state has presented several opportunities towards fault-tolerant quantum information processing. There is much current interest in combining superconductivity and spin–orbit coupling in order to induce the topological superconductor phase and associated Majoranalike quasiparticles which hold great promise towards faulttolerant quantum computing. We demonstrate coexisting superconducting correlations and spin–orbit coupling in molecular-beam-epitaxy-grown thin films of GeTe. The former is evidenced by a precipitous low-temperature drop in the electrical resistivity which is quelled by a magnetic field, and the latter manifests as a weak antilocalisation (WAL) cusp in the magnetotransport.
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