English

Supercurrent Interference in Semiconductor Nanowire Josephson Junctions

Mesoscale and Nanoscale Physics 2019-11-05 v3

Abstract

Semiconductor-superconductor hybrid systems provide a promising platform for hosting unpaired Majorana fermions towards the realisation of fault-tolerant topological quantum computing. In this study, we employ the Keldysh Non-Equilibrium Green's function formalism to model quantum transport in normal-superconductor junctions. We analyze III-V semiconductor nanowire Josephson junctions (InAs/Nb) using a three-dimensional discrete lattice model described by the Bogolubov-de Gennes Hamiltonian in the tight-binding approximation, and compute the Andreev bound state spectrum and current-phase relations. Recent experiments [Zuo et al., Phys. Rev. Lett. 119,187704 (2017)] and [Gharavi et al., arXiv:1405.7455v2 (2014)] reveal critical current oscillations in these devices, and our simulations confirm these to be an interference effect of the transverse sub-bands in the nanowire. We add disorder to model coherent scattering and study its effect on the critical current oscillations, with an aim to gain a thorough understanding of the experiments. The oscillations in the disordered junction are highly sensitive to the particular realisation of the random disorder potential, and to the gate voltage. A macroscopic current measurement thus gives us information about the microscopic profile of the junction. Finally, we study dephasing in the channel by including elastic phase-breaking interactions. The oscillations thus obtained are in good qualitative agreement with the experimental data, and this signifies the essential role of phase-breaking processes in III-V semiconductor nanowire Josephson junctions.

Keywords

Cite

@article{arxiv.1902.10947,
  title  = {Supercurrent Interference in Semiconductor Nanowire Josephson Junctions},
  author = {Praveen Sriram and Sandesh S Kalantre and Kaveh Gharavi and Jonathan Baugh and Bhaskaran Muralidharan},
  journal= {arXiv preprint arXiv:1902.10947},
  year   = {2019}
}

Comments

21 pages, 18 figures, Accepted for publication in Physical Review B

R2 v1 2026-06-23T07:53:54.207Z