Effects of chemical disorder and spin-orbit coupling on electronic-structure and Fermi-surface topology of YbSb-based monopnictides

In this work, we study the influence of disorder on the electronic structure of YbSb -- a rare-earth monopnictide featuring a simple rock-salt (B1) crystal structure and a well-defined Fermi surface topology -- by employing first-principles density functional theory (DFT). We focus on chemical disorder introduced through Te and Al doping, selected based on their thermodynamic stability in alloyed configurations, to understand how such perturbations modify the electronic states of YbSb. Our results indicate that Te doping predominantly introduces electron-like states at the \textit{X} and \textit{L} points, while Al doping leads to a suppression of hole-like states at $\Gamma$, effectively driving the system from a semimetallic state to one characterized by very narrow-gap behavior at $\Gamma$. This modulation of the Fermi surface, particularly the reduction of central hole pockets at $\Gamma$, plays a central role in altering inter-pocket scattering -- a mechanism critical for tuning quantum transport properties, including superconductivity. This disorder-driven modulation of the Fermi surface, particularly the suppression of central hole pockets at $\Gamma$, controls inter-pocket scattering, which is essential for optimizing quantum transport properties, including superconductivity. Our results show that disorder can be effectively used as a means of engineering band topology, thereby tuning quantum-related responses through tailored electronic structure.