1D InAs channels by selective area growth for topological superconductivity applications

Joon Sue Lee; Sukgeun Choi; Mihir Pendharkar; Anthony McFadden; Chris Palmstrom

1D InAs channels by selective area growth for topological superconductivity applications

ORAL

Abstract

Topological superconductivity has been realized using one-dimensional (1D) semiconductor nanowire-based systems. An important step towards topological quantum computation applications is to demonstrate complex nanostructures consisting of multiple 1D channels hosting the topological superconducting phases. Here, we demonstrate 1D in-plane InAs channels by selective-area growth on SiO₂-patterned InP substrates using chemical beam epitaxy and molecular beam epitaxy. This bottom-up approach of selective-area growth is promising for realizing the scalable networks of 1D semiconductor channels. We investigated the optimal growth conditions of epitaxial InAs on InP by varying V/III ratio, substrate temperature, and growth rate. The resulting surface morphology and the facet formation of InAs crystals also depend on the crystallographic orientation and dimensions of 1D channel. In addition to the growth studies, we also discuss the electronic transport properties of the selectively grown InAs channels in various growth conditions, orientations, and dimensions.

^*This work was funded by Microsoft Research.

March 8, 2018, 1:51 PM – March 8, 2018, 2:03 PM

Presenters

Joon Sue Lee
- University of California Santa Barbara
- California NanoSystems Institute, University of California, Santa Barbara
- University of California - Santa Barbara
- Materials Science, University of California - Santa Barbara
- Univ of California - Santa Barbara

Authors

Joon Sue Lee
- University of California Santa Barbara
- California NanoSystems Institute, University of California, Santa Barbara
- University of California - Santa Barbara
- Materials Science, University of California - Santa Barbara
- Univ of California - Santa Barbara
Sukgeun Choi
- Department of Electrical and Computer Engineering, University of California, Santa Barbara
Mihir Pendharkar
- University of California Santa Barbara
- Department of Electrical and Computer Engineering, University of California, Santa Barbara
- University of California - Santa Barbara
- Univ of California - Santa Barbara
Anthony McFadden
- Department of Electrical and Computer Engineering, University of California, Santa Barbara
- Materials, University of California Santa Barbara
Chris Palmstrom
- University of California Santa Barbara
- Materials Department, California NanoSystems Institute, Electrical and Computer Engineering, University of California
- University of California-Santa Barbara
- California Nanosystems Institute, Dept. of Electrical and Computer Engineering, and Dept. of Materials, Univ of California - Santa Barbara
- University of California - Santa Barbara
- Electronics & Computer Enginneering, University of California Santa Barbara
- Materials Department, University of California, Santa Barbara
- Materials, University of California Santa Barbara
- Univ of California - Santa Barbara