iScience (Mar 2019)

Regulation of Two-Dimensional Lattice Deformation Recovery

  • Jinxin Liu,
  • Lu Zhou,
  • Ke Huang,
  • Xianyin Song,
  • Yunxu Chen,
  • Xiaoyang Liang,
  • Jin Gao,
  • Xiangheng Xiao,
  • Mark H. Rümmeli,
  • Lei Fu

Journal volume & issue
Vol. 13
pp. 277 – 283

Abstract

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Summary: The lattice directly determines the electronic structure, and it enables controllably tailoring the properties by deforming the lattices of two-dimensional (2D) materials. Owing to the unbalanced electrostatic equilibrium among the dislocated atoms, the deformed lattice is thermodynamically unstable and would recover to the initial state. Here, we demonstrate that the recovery of deformed 2D lattices could be directly regulated via doping metal donors to reconstruct electrostatic equilibrium. Compared with the methods that employed external force fields with intrinsic instability and nonuniformity, the stretched 2D molybdenum diselenide (MoSe2) could be uniformly retained and permanently preserved via doping metal atoms with more outermost electrons and smaller electronegativity than Mo. We believe that the proposed strategy could open up a new avenue in directly regulating the atomic-thickness lattice and promote its practical applications based on 2D crystals. : Atomic Structure; Chemical Composition Analysis; Simulation in Materials Science Subject Areas: Atomic Structure, Chemical Composition Analysis, Simulation in Materials Science