Flux periodic oscillations and phase-coherent transport in GeTe nanowire-based devices

Jinzhong Zhang,Thomas Schäpers,Abdur-Rehman Jalil,Zhigao Hu,Jonas Kölzer,Martina Luysberg,Hans Lüth,Pok-Lam Tse,Jia Grace Lu,Gregory Panaitov,Detlev Grützmacher,Daniel Rosenbach

doi:10.1038/s41467-021-21042-5

Abstract

Despite the fact that GeTe is known to be a very interesting material for applications in thermoelectrics and for phase-change memories, the knowledge on its low-temperature transport properties is only limited. We report on phase-coherent phenomena in the magnetotransport of GeTe nanowires. From universal conductance fluctuations measured on GeTe nanowires with Au contacts, a phase-coherence length of about 280 nm at 0.5 K is determined. The distinct phase-coherence is confirmed by the observation of Aharonov–Bohm type oscillations for parallel magnetic fields. We interpret the occurrence of these magnetic flux-periodic oscillations by the formation of a tubular hole accumulation layer. For Nb/GeTe-nanowire/Nb Josephson junctions we obtained a critical current of 0.2 μA at 0.4 K. By applying a perpendicular magnetic field the critical current decreases monotonously with increasing field, whereas in a parallel field the critical current oscillates with a period of the magnetic flux quantum confirming the presence of a tubular hole channel.

Highlights

Despite the fact that GeTe is known to be a very interesting material for applications in thermoelectrics and for phase-change memories, the knowledge on its low-temperature transport properties is only limited
For the GeTe nanowires equipped with Nb contacts the proximity-induced superconductivity as well as critical temperature and magnetic field of Nb/GeTe-nanowire/Nb Josephson junctions are studied
The cross section for the GeTe nanowires has a rhombic shape with a side length of about 80 nm