We study the influence of sample termination on the electronic properties of the novel quantum spin Hall insulator monolayer 1T'-WTe₂. For this purpose, we construct an accurate, minimal 4-orbital tight-binding model with spin-orbit coupling by employing a combination of density-functional theory calculations, symmetry considerations, and fitting to experimental data. Based on this model, we compute energy bands and 2-terminal conductance spectra for various ribbon geometries with different terminations, with and without magnetic field.The provided repository contains all code and data to reproduce the results of this study.

We study the influence of sample termination on the electronic properties of the novel quantum spin Hall insulator monolayer 1T'-WTe₂. For this purpose, we construct an accurate, minimal 4-orbital tight-binding model with spin-orbit coupling by employing a combination of density-functional theory calculations, symmetry considerations, and fitting to experimental data. Based on this model, we compute energy bands and 2-terminal conductance spectra for various ribbon geometries with different terminations, with and without magnetic field.The provided repository contains all code and data to reproduce the results of this study.

We study the influence of sample termination on the electronic properties of the novel quantum spin Hall insulator monolayer 1T'-WTe₂. For this purpose, we construct an accurate, minimal 4-orbital tight-binding model with spin-orbit coupling by employing a combination of density-functional theory calculations, symmetry considerations, and fitting to experimental data. Based on this model, we compute energy bands and 2-terminal conductance spectra for various ribbon geometries with different terminations, with and without magnetic field.The provided repository contains all code and data to reproduce the results of this study.

We study the influence of sample termination on the electronic properties of the novel quantum spin Hall insulator monolayer 1T'-WTe₂. For this purpose, we construct an accurate, minimal 4-orbital tight-binding model with spin-orbit coupling by employing a combination of density-functional theory calculations, symmetry considerations, and fitting to experimental data. Based on this model, we compute energy bands and 2-terminal conductance spectra for various ribbon geometries with different terminations, with and without magnetic field.The provided repository contains all code and data to reproduce the results of this study.