Solar Harvesting Efficiency of Janus M<sub>2</sub>CTT′(M = Y, Sc; T/T′ = Br, Cl, F) MXene Monolayers for Photovoltaic Applications
Bill D. Aparicio-Huacarpuma, Marcelo Lopes Pereira, Alysson Martins Almeida Silva, Alexandre C. Dias, Luiz Antônio Ribeiro
Abstract
High Resolution Image Download MS PowerPoint Slide Two-dimensional (2D) Janus MXene monolayers have emerged as promising candidates for photovoltaic and optoelectronic applications due to their highly tunable physicochemical properties, which enable optimized light absorption and enhanced power conversion efficiency (PCE). In this study, we investigate the structural, electronic, excitonic, and optical properties of 2D Janus MXenes with the general formula M 2 CTT′ (M = Sc, Y; TT′ = FCl, FBr, ClBr) using density functional theory calculations combined with a semiempirical tight-binding approach. All six monolayers are found to be structurally stable, exhibiting a trigonal configuration with cohesive energies ranging from −5.74 eV/atom to −5.22 eV/atom. Their electronic band structures reveal an indirect semiconducting nature, with band gaps spanning 1.63 to 1.83 eV. The computed linear optical properties indicate strong absorption in the visible, infrared, and ultraviolet regions, reinforcing their potential for solar energy harvesting. Strong many-body effects are observed, with exciton binding energies between 249 and 373 meV, which are crucial for accurately describing energy conversion processes. The estimated PCE, evaluated using both the Shockley–Queisser (SQ) limit and the pectroscopy-limited maximum efficiency (SLME) approach, ranges from 25.5% to 32.6%, positioning these Janus M 2 CTT′ MXenes as strong contenders for next-generation photovoltaic devices.