Theory of magneto-elastoresistance and application to WTe₂: exploring electronic structure and extremely large magnetoresistance under strain

The application of uniaxial stress to is a promising route to probe and control the properties of quantum materials. One crucial step is to quantify the effects of strain on the electronic band structure, carrier density and mobility. Here, we demonstrate that much information can be obtained by exploring a novel experimental observable: magneto-elastoresistance (MER), which refers to magnetic field-driven changes of the elastoresistance. We apply this powerful approach to study the combined effect of strain and magnetic fields on the semi-metallic transition metal dichalcogenide WTe₂, and discover a large and temperature non-monotonic elastoresistance (ER) that can be tuned by magnetic field. We report on our theoretical analysis of these observations based on semi-classical Boltzmann transport theory combined with input from first-principles calculations. We highlight how MER can generally yield new insights beyond the zero field ER. For WTe₂ specifically we derive an effective low-energy three-band model that can account for the salient experimental features.