npj Quantum Materials (Mar 2022)

Nanoscale studies of electric field effects on monolayer 1T′-WTe2

  • Yulia Maximenko,
  • Yueqing Chang,
  • Guannan Chen,
  • Mark R. Hirsbrunner,
  • Waclaw Swiech,
  • Taylor L. Hughes,
  • Lucas K. Wagner,
  • Vidya Madhavan

DOI
https://doi.org/10.1038/s41535-022-00433-x
Journal volume & issue
Vol. 7, no. 1
pp. 1 – 6

Abstract

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Abstract Monolayer 1 T′-WTe2 is a quantum spin Hall insulator with a gapped 2D-bulk and gapless helical edge states persisting to temperatures ~100 K. Despite the far-ranging interest, the magnitude of the bulk gap, the effect of gating on the 2D-band structure, as well the role interactions are not established. In this work we use STM spectroscopy to measure the intrinsic bulk gap of monolayer 1 T′-WTe2 and show that gate induced electric fields cause large changes of the gap magnitude. Our first-principles DFT-derived tight-binding model reveal that a combination of spatial localization of the conduction and valance bands and Rashba-like spin-orbit coupling leads to a gating induced spin-splitting of the 2D-bulk bands in the tens of meV, thereby reducing the band gap. Our work explains the large sensitivity of the band structure to electric fields and suggests a new avenue for realizing proximity induced non-trivial superconductivity in monolayer 1 T′-WTe2.