Proximity-Induced Superconductivity in Topological Crystalline Insulator Thin Films

ORAL

Abstract

Over the past decades, topological superconductivity has attracted much attention due to its potential to host Majorana zero modes. One approach for realizing topological superconductivity is through a topological insulator proximally coupled to an s-wave superconductor. Unlike topological insulators, where topology is protected by time-reversal symmetry, topological crystalline insulators (TCIs) exhibit topological surface states protected by crystal mirror symmetry. In this work, we used molecular beam epitaxy to grow TCI SnTe thin films and fabricated lateral Josephson junction devices. Through AC and DC Josephson measurements, we demonstrated proximity-induced superconductivity in SnTe. By analyzing Fraunhofer patterns under varying in-plane magnetic fields along the current direction, we examined the evolution of current distribution in these devices. TCI thin films with proximity-induced superconductivity provide a promising platform for exploring multiple Majorana zero modes.

*This work is supported by NSF award (DMR-2241327), ONR award (N000142412133), and Gordon and Betty Moore Foundation’s EPiQS Initiative (Grant GBMF9063 to C. -Z. C.).

Presenters

  • Xiaoda Liu

    • Pennsylvania State University
    • The Pennsylvania State University

Authors

  • Xiaoda Liu

    • Pennsylvania State University
    • The Pennsylvania State University

  • Bomin Zhang

    • Pennsylvania State University
    • The Pennsylvania State University

  • Zi-Jie Yan

    • The Pennsylvania State University
    • Pennsylvania State University

  • Hongtao Rong

    • Pennsylvania State University
    • The Pennsylvania State University

  • Zhiyuan Xi

    • Pennsylvania State University

  • Lingjie Zhou

    • Pennsylvania State University
    • The Pennsylvania State University

  • Cui-Zu Chang

    • Pennsylvania State University
    • The Pennsylvania State University