Achieving Large Uniaxial and Homogeneous Strain in Two-Dimensional Materials

TL;DR

This paper introduces a novel, high-precision platform for applying large, uniform, and reversible uniaxial strain to 2D materials, enabling systematic exploration of strain-induced phenomena.

Contribution

The authors develop a reliable, scalable method to achieve and control high levels of uniaxial strain in various 2D materials, surpassing previous limitations.

Findings

Achieved reversible uniaxial strain up to ~4% in CrSBr with negligible slippage.

Demonstrated uniform strain gradients of up to 0.06%/μm across tens of micrometers.

Validated the platform's applicability to multiple transition metal dichalcogenides, including record 5.5% strain in WTe₂.

Abstract

Strain engineering is a powerful tool for tuning the electronic, magnetic, and topological properties of two-dimensional (2D) materials and thin films - particularly at high values of strain (>3%) where many electronic, magnetic, and structural transitions have been predicted. However, most approaches to tuning strain in 2D materials are limited below 1.5%, with poor repeatability when cycling strain and low strain transfer when cooling to cryogenic temperatures. Here, we report a high-yield sample preparation and device strain platform that overcomes these limitations, enabling precise, reversible strain tuning up to the intrinsic strain-to-failure of the materials tested herein. In addition, we show that this platform can be used to controllably design uniform linear strain gradients across of 10's of $\mu$m, providing a novel route to systematically investigate flexoelectric and flexomagnetic phenomena. Using CrSBr as a model system, we demonstrate uniform uniaxial strain, up to ~4%, with negligible slippage and linear strain gradients of up to 0.06%/$\mu$m. We further show that our strain approach is applicable to a broad class of 2D materials, validating its performance for three different phases of transition metal dichalcogenides: 2H-MoTe$_2$, 1T$^\prime$-MoTe$_2$ and T$_\mathrm{d}$-WTe$_2$. In T$_\mathrm{d}$-WTe$_2$, verified by theoretical calculations, we show a continuous redshift of the A$_1^3$ mode, up to a record-breaking ~5.5% strain, with a clear separation of the A$_1^3$ and A$_1^2$ modes starting at 2% strain.