Abstract
In flexible 2D-devices, strain transfer between different van-der Waals stacked layers is expected to play an important role in determining their optoelectronic performances and mechanical stability. Using a 2D non-linear shear-lag model, we demonstrate that only 1-2% strain can be transferred between adjacent layers of different 2d-materials, depending on the strength of the interlayer vdW interaction and the elastic modulus of the individual layers. Beyond this critical strain, layers begin to slip with respect to each other. We further show that due to the symmetry of the periodic interlayer shear potential, stacked structures form strain solitons with alternating AB/BA or AB/AB stacking which are separated by incommensurate domain walls. The extent and the separation distance of these commensurate domains are found to be determined by the degree of the applied strain, and their magnitudes are calculated for several 2D heterostructures and bilayers including MoS2/WS2, MoSe2/WSe2, Graphene/Graphene and MoS2/MoS2 using a multiscale method. As bilayer structures have been shown to exhibit stacking-dependent electronic bandgap and quantum transport properties, the predictions of our study will not only be crucial in determining the mechanical stability of flexible 2D devices but will also help to better understand optoelectronic response of flexible devices.
Highlights
Is stretched) while the top layer is free to deform
We have developed and implemented multiscale formulation based on a non-linear shear-lag model to investigate the mechanism of the strain transfer between different layers of 2D materials
Heterostructures without any lattice mismatch have an interlayer shear potential whose periodicity is identical to the lattice periodicity
Summary
Is stretched) while the top layer is free to deform. This model for a bilayer system can be generalized for the multilayer systems. Heterostructures of GR-hBN deform to form moiré patterns when the two layers are in perfect alignment, but decouple from each other when the misalignment angle is larger than 10° 15,16 This interplay of energies is the basic premise of the shear-lag model studied here. Linear elastic models have been used to study the strain transfer in multiwall carbon nanotubes[17] and polymer-composites[18] These linear models cannot predict the formation of strain solitons and fail to provide estimates for the critical strain at which interface sliding and debonding occurs. To address these issues, we have developed and implemented multiscale formulation based on a non-linear shear-lag model to investigate the mechanism of the strain transfer between different layers of 2D materials. We present theoretical predictions for strain transfer and debonding in other vdW heterostructures, namely, MoS2/MoS2, WS2/WS2, MoSe2/WSe2, MoSe2/MoSe2, and WSe2/WSe2
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