Tuning Terahertz Optomechanics of MoS2 Bilayers with Homogeneous In-plane Strain

TL;DR

This study demonstrates how homogeneous in-plane biaxial tensile strain in MoS2 bilayers enhances interlayer interactions, enabling precise tuning of terahertz oscillations and revealing highly nonlinear mechanical properties driven by geometric contraction.

Contribution

The paper introduces a method to tune terahertz optomechanics in MoS2 bilayers via homogeneous strain, revealing unprecedented nonlinear mechanical behavior and strong light coupling without external pressure.

Findings

Strain-induced hardening of interlayer breathing modes observed.

Poisson contraction drives the system into a highly repulsive potential regime.

Grüneisen parameter exceeds values reported for phosphorene.

Abstract

Homogeneous in-plane biaxial tensile strain strengthens the out-of-plane van der Waals interaction in \MoS\ bilayers (BLs) and can be used to fine-tune their terahertz (THz) oscillations. Using ultralow-frequency Raman spectroscopy on hexagonal (2H) and rhombohedral (2R) stacked BLs, we observe a hardening of the interlayer breathing modes originating from a strain-induced Poisson contraction of the vdW separation between the layers, and characterized by an effective out-of-plane Poisson's ratio of $\nu_\mathrm{eff} \approx 0.19\text{--}0.24$. Strikingly, this geometric contraction drives the system into a highly repulsive regime of the intermolecular potential, corresponding to a Gr\"uneisen parameter of $\gamma \approx 10\text{--}14$. This value surpasses even the `giant' one reported for phosphorene, establishing these van der Waals BLs as highly tunable nonlinear mechanical platforms that can be addressed at the THz regime, couple strongly with light, and do not need external pressure knobs.