Topological columnar nano-SQUID based on a 3D topological insulator

Ella Nikodem, Jakob Schluck, Henry F. Legg, Max Geier, Michal Papaj, Mahasweta Bagchi, Liang Fu, Yoichi Ando

Published 2024-12-11Version 1

A 3D topological insulator (TI) is wrapped by a metallic surface that is topologically protected. While this surface is promising for generating non-Abelian Majorana zero-modes (MZMs) for topological quantum computing, it is a challenge to gap out the whole surface to get rid of low-energy quasiparticles to realize a well-defined fermion parity. Here we propose a novel TI platform that solves this problem and gives rise to a robust topological phase. It consists of a bulk-insulating rectangular TI nanowire laterally sandwiched by two superconductors. In this structure, the top and bottom surfaces individually work as SNS line junctions, forming a nanometer-scale columnar SQUID in which the nanowire cross-section defines the threading flux $\Phi$. We demonstrate that a TI device of this structure indeed presents SQUID-type oscillations of the critical current $I_c$ as a function of the axial magnetic field with period $\Phi_{0}^s=\frac{h}{2e}$ and can be tuned by a back gate to attain vanishing $I_c$ minima, an indication that the supercurrent is completely surface-dominated. Our theory shows that, when the two junctions are asymmetric, a robust topological phase hosting MZMs occurs periodically for $(n-\frac{1}{2})\Phi_{0}^s < \Phi < (n+\frac{1}{2})\Phi_{0}^s$ with odd-integer $n$.