Role of a capping layer on the crystalline structure of Sn thin films grown at cryogenic temperatures on InSb substrates

An Hsi Chen, Connor Dempsey, Mihir Pendharkar, Amritesh Sharma, Bomin Zhang, Susheng Tan, Ludovic Bellon, Sergey M. Frolov, Christopher J. Palmstrøm, Edith Bellet-Amalric, Moïra Hocevar

Research output: Contribution to journalArticlepeer-review

Abstract

Metal deposition with cryogenic cooling is a common technique in the condensed matter community for producing ultra-thin epitaxial superconducting layers on semiconductors. However, a significant challenge arises when these films return to room temperature, as they tend to undergo dewetting. This issue can be mitigated by capping the films with an amorphous layer. In this study, we investigate the influence of different in situ fabricated caps on the structural characteristics of Sn thin films deposited at 80 K on InSb substrates. Regardless of the type of capping, we consistently observe that the films remain smooth upon returning to room temperature and exhibit epitaxy on InSb in the cubic Sn (α-Sn) phase. Notably, we identify a correlation between alumina capping using an electron beam evaporator and an increased presence of tetragonal Sn (β-Sn) grains. This suggests that heating from the alumina source may induce a partial phase transition in the Sn layer. The existence of the β-Sn phase induces superconducting behavior of the films by percolation effect. This study highlights the potential for tailoring the structural properties of cryogenic Sn thin films through in situ capping. This development opens avenues for precise control in the production of superconducting Sn films, facilitating their integration into quantum computing platforms.

Original languageEnglish
Article number075702
JournalNanotechnology
Volume35
Issue number7
DOIs
StatePublished - Feb 12 2024
Externally publishedYes

Funding

The work in Grenoble was supported by ANR HYBRID (ANR-17-PIRE-0001), IRP HYNATOQ and the Transatlantic Research Partnership. Work at the University of Pittsburgh and UCSB was supported by the National Science Foundation (NSF) PIRE-1743717.

FundersFunder number
ANR-17-PIRE-0001
National Science FoundationPIRE-1743717
University of Pittsburgh
Institute for Research on Poverty
Agence Nationale de la Recherche

    Keywords

    • Sn
    • cryogenic growth
    • hybrid materials
    • thin film epitaxy
    • x-ray diffraction

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