Inducing superconductivity in Weyl semimetal microstructures by selective ion sputtering

Maja D. Bachmann, Nityan Nair, Felix Flicker, Roni Ilan, Tobias Meng, Nirmal J. Ghimire, Eric D. Bauer, Filip Ronning, James G. Analytis, Philip J.W. Moll*

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

64 Scopus citations

Abstract

By introducing a superconducting gap in Weyl or Dirac semimetals, the superconducting state inherits the nontrivial topology of their electronic structure. As a result, Weyl superconductors are expected to host exotic phenomena, such as nonzero-momentum pairing due to their chiral node structure, or zero-energy Majorana modes at the surface. These are of fundamental interest to improve our understanding of correlated topological systems, and, moreover, practical applications in phase-coherent devices and quantum applications have been proposed. Proximity-induced superconductivity promises to allow these experiments on nonsuperconducting Weyl semimetals. We show a new route to reliably fabricate superconducting microstructures from the nonsuperconducting Weyl semimetal NbAs under ion irradiation. The significant difference in the surface binding energy of Nb and As leads to a natural enrichment of Nb at the surface during ion milling, forming a superconducting surface layer (Tc ∼ 3.5 K). Being formed from the target crystal itself, the ideal contact between the superconductor and the bulk may enable an effective gapping of the Weyl nodes in the bulk because of the proximity effect. Simple ion irradiation may thus serve as a powerful tool for the fabrication of topological quantum devices from monoarsenides, even on an industrial scale.

Original languageEnglish
Article numbere1602983
JournalScience advances
Volume3
Issue number5
DOIs
StatePublished - May 2017

Funding

FundersFunder number
National Science Foundation
U.S. Department of Energy
Directorate for Education and Human Resources1106400
Office of Science
Engineering and Physical Sciences Research CouncilEP/I007002/1
Deutsche ForschungsgemeinschaftGRK 1621, SFB 1143

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