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Superconductivity in FeTe-Based Heterostructures

ORAL

Abstract

FeTe is an antiferromagnetic iron chalcogenide metal with a crystal structure identical to FeSe. Unlike superconducting FeSe, FeTe does not exhibit superconductivity, which is usually attributed to its bi-collinear antiferromagnetic order. In this work, we employed molecular beam epitaxy to synthesize a series of FeTe-based heterostructures, including (Bi,Sb)2Te3/FeTe, Cr-doped (Bi,Sb)2Te3/FeTe, MnBi2Te4/FeTe, CrTe2/FeTe, and SnTe/FeTe. Our electrical transport measurements reveal that these heterostructures show superconductivity with a critical superconducting transition temperature of ~11 K. Moreover, by performing in-situ spin-polarized scanning tunneling microscopy/spectroscopy measurements, we observed that a superconducting gap emerges once the bi-collinear antiferromagnetic order in the FeTe layer is suppressed. This work provides new insights into the mechanisms responsible for superconductivity in FeTe-based heterostructures.

Presenters

  • Zi-Jie Yan

    The Pennsylvania State University, Pennsylvania State University

Authors

  • Zi-Jie Yan

    The Pennsylvania State University, Pennsylvania State University

  • Zihao Wang

    Pennsylvania State University

  • Bing Xia

    Pennsylvania State University, The Pennsylvania State University

  • Stephen Paolini

    Pennsylvania State University

  • Hongtao Rong

    Pennsylvania State University, The Pennsylvania State University

  • Annie G Wang

    The Pennsylvania State University, Pennsylvania State University

  • Pu Xiao

    Pennsylvania State University, The Pennsylvania State University

  • Veer Gowda

    Pennsylvania State University, The Pennsylvania State University

  • Jiatao Song

    Pennsylvania State University, The Pennsylvania State University

  • Cui-Zu Chang

    Pennsylvania State University, The Pennsylvania State University