Abstract
Antimony selenide (Sb(2)Se(3)) shows promise for photovoltaics due to its favorable properties and low toxicity. However, current Sb(2)Se(3) solar cells exhibit efficiencies significantly below their theoretical limits, primarily due to interface recombination and non-optimal device architectures. This study presents a comprehensive numerical investigation of Sb(2)Se(3) thin-film solar cells using SCAPS-1D simulation software, focusing on device architecture optimization and interface engineering. We systematically analyzed device configurations (substrate and superstrate), hole-transport layer (HTL) materials (including NiOx, CZTS, Cu(2)O, CuO, CuI, CuSCN, CZ-TA, and Spiro-OMeTAD), layer thicknesses, carrier densities, and resistance effects. The substrate configuration with molybdenum back contact demonstrated superior performance compared with the superstrate design, primarily due to favorable energy band alignment at the Mo/Sb(2)Se(3) interface. Among the investigated HTL materials, Cu(2)O exhibited optimal performance with minimal valence-band offset, achieving maximum efficiency at 0.06 μm thickness. Device optimization revealed critical parameters: series resistance should be minimized to 0-5 Ω-cm(2) while maintaining shunt resistance above 2000 Ω-cm(2). The optimized Mo/Cu(2)O(0.06 μm)/Sb(2)Se(3)/CdS/i-ZnO/ITO/Al structure achieved a remarkable power conversion efficiency (PCE) of 21.68%, representing a significant improvement from 14.23% in conventional cells without HTL. This study provides crucial insights for the practical development of high-efficiency Sb(2)Se(3) solar cells, demonstrating the significant impact of device architecture optimization and interface engineering on overall performance.