Nature Communications (May 2024)

Remote epitaxy of single-crystal rhombohedral WS2 bilayers

  • Chao Chang,
  • Xiaowen Zhang,
  • Weixuan Li,
  • Quanlin Guo,
  • Zuo Feng,
  • Chen Huang,
  • Yunlong Ren,
  • Yingying Cai,
  • Xu Zhou,
  • Jinhuan Wang,
  • Zhilie Tang,
  • Feng Ding,
  • Wenya Wei,
  • Kaihui Liu,
  • Xiaozhi Xu

DOI
https://doi.org/10.1038/s41467-024-48522-8
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 7

Abstract

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Abstract Compared to transition metal dichalcogenide (TMD) monolayers, rhombohedral-stacked (R-stacked) TMD bilayers exhibit remarkable electrical performance, enhanced nonlinear optical response, giant piezo-photovoltaic effect and intrinsic interfacial ferroelectricity. However, from a thermodynamics perspective, the formation energies of R-stacked and hexagonal-stacked (H-stacked) TMD bilayers are nearly identical, leading to mixed stacking of both H- and R-stacked bilayers in epitaxial films. Here, we report the remote epitaxy of centimetre-scale single-crystal R-stacked WS2 bilayer films on sapphire substrates. The bilayer growth is realized by a high flux feeding of the tungsten source at high temperature on substrates. The R-stacked configuration is achieved by the symmetry breaking in a-plane sapphire, where the influence of atomic steps passes through the lower TMD layer and controls the R-stacking of the upper layer. The as-grown R-stacked bilayers show up-to-30-fold enhancements in carrier mobility (34 cm2V−1s−1), nearly doubled circular helicity (61%) and interfacial ferroelectricity, in contrast to monolayer films. Our work reveals a growth mechanism to obtain stacking-controlled bilayer TMD single crystals, and promotes large-scale applications of R-stacked TMD.