Superconducting proximity effect in three-dimensional topological insulators in the presence of a magnetic field

Pablo Burset, Bo Lu, Grigory Tkachov, Yukio Tanaka, Ewelina M. Hankiewicz, Bjoern Trauzettel

Published 2015-08-28Version 1

The proximity induced pair potential in a topological insulator-superconductor hybrid features an interesting superposition of a conventional spin-singlet component from the superconductor and a spin-triplet one induced by the surface state of the topological insulator. This singlet-triplet superposition can be controlled by an external magnetic field. We study the interplay between topological order and superconducting correlations performing a symmetry analysis of the induced pair potential, using Green functions techniques to theoretically describe ballistic junctions between superconductors and topological insulators under external magnetic fields. We relate a change in the conductance from a gapped profile into one with a zero-energy peak with the transition into a topologically nontrivial regime where the odd-frequency triplet pairing becomes the dominant component in the pair potential. The nontrivial regime, which provides a signature of odd-frequency triplet superconductivity, is reached for out-of-plane magnetic fields with strength comparable to the chemical potential of the superconductor or for in-plane fields, parallel to the normal-superconductor interface, with strength of the order of the superconducting gap. Strikingly, in the latter case, if the field is misaligned with the interface, the conductance becomes asymmetric with the energy unless the total contribution of the topological surface state is considered.