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Hauptverfasser: Beck, Philip, Nyári, Bendegúz, Schneider, Lucas, Rózsa, Levente, Lászlóffy, András, Palotás, Krisztián, Szunyogh, László, Ujfalussy, Balázs, Wiebe, Jens, Wiesendanger, Roland
Format: Preprint
Veröffentlicht: 2023
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Online-Zugang:https://arxiv.org/abs/2301.05622
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author Beck, Philip
Nyári, Bendegúz
Schneider, Lucas
Rózsa, Levente
Lászlóffy, András
Palotás, Krisztián
Szunyogh, László
Ujfalussy, Balázs
Wiebe, Jens
Wiesendanger, Roland
author_facet Beck, Philip
Nyári, Bendegúz
Schneider, Lucas
Rózsa, Levente
Lászlóffy, András
Palotás, Krisztián
Szunyogh, László
Ujfalussy, Balázs
Wiebe, Jens
Wiesendanger, Roland
contents One-dimensional systems comprising s-wave superconductivity with meticulously tuned magnetism and spin-orbit coupling can realize topologically gapped superconductors hosting Majorana edge modes whose stability is determined by the gap's size. The ongoing quest for larger topological gaps evolved into a material science issue. However, for atomic spin chains on superconductor surfaces, the effect of the substrate's spin-orbit coupling on the system's topological gap size is largely unexplored. Here, we introduce an atomic layer of the heavy metal Au on Nb(110) which combines strong spin-orbit coupling and a large superconducting gap with a high crystallographic quality enabling the assembly of defect-free Fe chains using a scanning tunneling microscope tip. Scanning tunneling spectroscopy experiments and density functional theory calculations reveal ferromagnetic coupling and ungapped YSR bands in the chain despite of the heavy substrate. By artificially imposing a spin spiral state our calculations indicate a minigap opening and zero-energy edge state formation. The presented methodology paves the way towards a material screening of heavy metal layers on elemental superconductors for ideal systems hosting Majorana edge modes protected by large topological gaps.
format Preprint
id arxiv_https___arxiv_org_abs_2301_05622
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Search for large topological gaps in atomic spin chains on proximitized superconducting heavy metal layers
Beck, Philip
Nyári, Bendegúz
Schneider, Lucas
Rózsa, Levente
Lászlóffy, András
Palotás, Krisztián
Szunyogh, László
Ujfalussy, Balázs
Wiebe, Jens
Wiesendanger, Roland
Superconductivity
One-dimensional systems comprising s-wave superconductivity with meticulously tuned magnetism and spin-orbit coupling can realize topologically gapped superconductors hosting Majorana edge modes whose stability is determined by the gap's size. The ongoing quest for larger topological gaps evolved into a material science issue. However, for atomic spin chains on superconductor surfaces, the effect of the substrate's spin-orbit coupling on the system's topological gap size is largely unexplored. Here, we introduce an atomic layer of the heavy metal Au on Nb(110) which combines strong spin-orbit coupling and a large superconducting gap with a high crystallographic quality enabling the assembly of defect-free Fe chains using a scanning tunneling microscope tip. Scanning tunneling spectroscopy experiments and density functional theory calculations reveal ferromagnetic coupling and ungapped YSR bands in the chain despite of the heavy substrate. By artificially imposing a spin spiral state our calculations indicate a minigap opening and zero-energy edge state formation. The presented methodology paves the way towards a material screening of heavy metal layers on elemental superconductors for ideal systems hosting Majorana edge modes protected by large topological gaps.
title Search for large topological gaps in atomic spin chains on proximitized superconducting heavy metal layers
topic Superconductivity
url https://arxiv.org/abs/2301.05622