Many-body \textit{ab initio} study of quasiparticle \& optical excitations and exciton analysis in LiZnAs and ScAgC for photovoltaic applications (2504.00990v1)

Published 1 Apr 2025 in cond-mat.mtrl-sci

Abstract: Using first-principles density-functional theory and many-body excited-state calculations, we study the quasiparticle band structure, optical and excitonic properties of two half-Heusler (HH) compounds, namely LiZnAs and ScAgC, for photovoltaic (PV) applications. Our results reveal a direct bandgap semiconducting behavior in LiZnAs (ScAgC) with a value of 1.5 (1.0) eV under an accurate G$_0$W$_0$ calculation. The highest value of the imaginary part of dielectric function is found as 52 (87), 77 (87), 88 (91) using the independent-quasiparticle approximation, local field effects in random-phase approximation, and electron-hole interaction in the Bethe-Salpeter equation, respectively. Both materials demonstrate a high refractive index, high absorption coefficients (1.2-1.6 $\times 10⁶ cm^{-1}$), and low reflectivity (< 40%) in active region of the solar spectrum. The triply degenerate bright excitons (exciton A) at the main absorption peak and a considerable number of bright excitonic states in the visible region, are observed; however, the excitons oscillator strength are comparatively weaker in ScAgC than in LiZnAs. We further discuss the exciton character contributing to intense optical interband transitions and reveal that direct band gap is associated to the loosely bound exciton A state with binding energy of 45 (56) meV in LiZnAs (ScAgC). Exciton A is found to be highly localized (delocalized) in momentum (real) space, indicating the presence of Mott-Wannier type excitons at bandgap. Finally, we assess the solar efficiencies using the spectroscopic limited maximum efficiency (SLME) model and find SLME values of 32% for LiZnAs and 31% for ScAgC at a 0.4 $\mu$m thin-film thickness. These findings highlight the significant role of excitons in solar energy absorption process and also suggest that both are highly suitable candidates for single-junction thin-film solar cells.