Bond Dipole Theory of Band Offset

Understanding the band offset between materials is pivotal for electronic device functionality. While traditional theories attribute this offset solely to intrinsic properties of constituent materials, interfacial chemistry introduces complexities, including charge transfer dipoles. We address this challenge by defining a reference system based on Wigner-Seitz atoms, which is a charge partitioning that tessellates space while retaining bulk crystal symmetry. The interfacial dipole is then expressed entirely by localized dipoles along interfacial bonds. Geometric analysis reveals that for isotropic materials, both bulk and interfacial contributions to the band offset are orientation independent. This finding is confirmed through first-principles calculations and analysis of 28 distinct interfaces, which show very little (< 0.1 eV) dependence on orientation. Furthermore, the direction dependence of anisotropic materials is well captured by the theory. This work provides crucial insights into the geometric underpinnings of band offset, offering a comprehensive understanding essential for advancing materials design in electronic applications.