posted on 2022-07-15, 15:37authored byYong Han, Dapeng Jing, Yilong Luan, Chi-Jen Wang, Marek Kolmer, Zhe Fei, Michael C. Tringides, James W. Evans
Thermodynamic and kinetic analyses based on our first-principles
density functional theory calculations are used to interpret the experimentally
observed formation of Cu carpets intercalated under the top layer
of a 2H-MoS2 substrate. Spontaneous Cu
transport from Cu pyramids on top of the MoS2 substrate
through surface point defects to the growing Cu carpet is shown to
be driven by a slightly lower chemical potential for the Cu carpet.
We demonstrate that the competition between a preference for a thicker
Cu carpet and the cost of elastic stretching of the top MoS2 layer results in a selected Cu carpet thickness. We also propose
that Cu transport occurs primarily via vacancy-mediated diffusion
through constricting point defect portals.