Interface-Driven Partial Dislocation Formation in 2D Heterostructures

Abstract

Van der Waals (vdW) epitaxy allows the fabrication of various heterostructures with dramatically released lattice matching conditions. This study demonstrates interface-driven stacking boundaries in WS 2 using epitaxially grown tungsten disulfide (WS 2 ) on wrinkled graphene. Graphene wrinkles function as highly reactive nucleation sites on WS 2 epilayers; however, they impede lateral growth and induce additional stress in the epilayer due to anisotropic friction. Moreover, partial dislocation-driven in-plane strain facilitates out-of-plane buckling with a height of 1 nm to release in-plane strain. Remarkably, in-plane strain relaxation at partial dislocations restores the bandgap to that of monolayer WS 2 due to reduced interlayer interaction. These findings clarify significant substrate morphology effects even in vdW epitaxy and are potentially useful for various applications involving modifying optical and electronic properties by manipulating extended 1D defects via substrate morphology control. © 2019 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim