Quantitative measurement of layer-to-layer electronic coupling in bilayer MoS₂

Interlayer electronic coupling plays a critical role in determining the electronic properties of van der Waal (vdW) bilayers. In particular, the coupling strength is dictated by the stacking configuration and the interlayer spacing. While the former has been well established, the influence of interlayer spacing still remains largely unexplored. Here, by measuring the optical transition of bilayer MoS₂ in the diamond anvil cell, we quantitatively determined the interlayer coupling at various critical points of the Brillouin zone. The K-point coupling strength we obtained is ~40 meV, which can be increased to more than 100 meV at a reduced interlayer spacing of ~8%. In addition, the energy evolution of the indirect gap is used to measure the coupling strength of Q and Γ points. All experimental results are compared with the density functional theory. Our work has confirmed the great potential in tailoring vdW bilayers using compressive pressure.