Magnetotransport in graphene/Pb0.24Sn0.76Te heterostructures: finding a way to avoid catastrophe

TL;DR

This study demonstrates a hybrid graphene/Pb0.24Sn0.76Te heterostructure with enhanced magnetotransport properties, revealing two transport channels and a lower bound on spin relaxation time, advancing potential spintronic applications.

Contribution

It introduces a novel graphene/PST heterostructure exhibiting improved transport properties and identifies the underlying polar catastrophe mechanism influencing these behaviors.

Findings

Carrier mobility up to 20,000 cm2/Vs

Magnetoresistance approaching 100%

Lower bound on spin relaxation time of 4.5 ps

Abstract

While heterostructures are ubiquitous tools enabling new physics and device functionalities, the palette of available materials has never been richer. Combinations of two emerging material classes, two-dimensional materials and topological materials, are particularly promising because of the wide range of possible permutations that are easily accessible. Individually, both graphene and Pb0.24Sn0.76Te (PST) are widely investigated for spintronic applications because graphene's high carrier mobility and PST's topologically protected surface states are attractive platforms for spin transport. Here, we combine monolayer graphene with PST and demonstrate a hybrid system with properties enhanced relative to the constituent parts. Using magnetotransport measurements, we find carrier mobilities up to 20,000 cm2/Vs and a magnetoresistance approaching 100 percent, greater than either material prior to stacking. We also establish that there are two distinct transport channels and determine a lower bound on the spin relaxation time of 4.5 ps. The results can be explained using the polar catastrophe model, whereby a high mobility interface state results from a reconfiguration of charge due to a polar/non-polar interface interaction. Our results suggest that proximity induced interface states with hybrid properties can be added to the still growing list of remarkable behaviors in these novel materials.