Unveiling the optoelectronic structure and photovoltaic potential of ZrO@GO through cosensitization with squaraine dye in DSSC: a computational study

The quest to enhance solar cell performance has long been driven by increasing energy demands and environmental concerns, and much progress has been achieved by way of interface modifications. As the demand for sustainable energy increases and environmental awareness pushes us toward cleaner solutions, the spotlight turns to stable and eco-friendly metal oxide semiconductors for photovoltaic applications. This research highlights the exceptional electronic and optical characteristics of ZrO 2 @GO nanoparticles, focusing on molecular electrostatic potential (MEP), nonlinear optical properties (NLO), and electron localization function (ELF). Our findings highlight that ZrO 2 @GO exhibits superior electronic characteristics compared to bare graphene oxide. This superiority motivates us for the co-sensitization of ZrO 2 @GO with squaraine dyes, which are well known for their strong light harvesting in dye-sensitized solar cells (DSSC). Using density functional theory (DFT) with Gaussian 09, we examine critical parameters that include the highest occupied molecular orbital (HOMO), lowest unoccupied molecular orbital (LUMO), energy gap, maximum wavelength ( λ max ), electron injection efficiency (Δ G inject ), open-circuit voltage ( V oc ), reorganization energy ( λ reorg ), among others. Our research highlights the high optical transmittance of ZrO 2 @GO, positioning it as a promising material for advanced optical, electrical, and light-harvesting devices with improved performance and efficiency. The quest to enhance solar cell performance has long been driven by increasing energy demands and environmental concerns, and much progress has been achieved by way of interface modifications.