Fabrication of omnidirectional broadband dual-functional coating with high optical and self-cleaning properties for photovoltaic application

Abstract

Escalating the transmitted irradiation, which diminishes due to the undesirable reflection at the interfaces and the surface dirt, requires a simultaneous functioning of antireflection and self-cleaning coating for photovoltaic modules. In this regard, an unprecedented, facile, economical, reproducible, and eco-friendly fabrication of dual-functional coatings (Anti-reflective and Self-cleaning) with high optical and photocatalytic properties is demonstrated. Highly crystalline MgF2 and TiO2 nanoparticles are successfully synthesized by the solvothermal method, and these nanoparticles are utilized to develop a dual-functional coating. HR-TEM and XRD are used to analyze the synthesized nanoparticles, and FE-SEM measures the coating morphology and thickness. The established dual-functional coating exhibits a 5 % enhancement in transmittance compared to uncoated glass in the 380–1100 nm wavelength range. The developed coating also shows high omnidirectional broadband antireflective property with 5–33 % net enhancement in the transmittance in the angle of incidence from 10 to 80°. The coating also exhibited good photocatalytic self-cleaning activity by degrading Methylene blue solution in 3 h with minimal loss in transmission. The bilayer dual-functional coating exhibited a net enhancement of 3.5 % in the power conversion efficiency for coated glass placed over a mini-module compared to uncoated glass positioned over a mini-module. This bilayer dual-functional coating offers enormous potential benefits and is highly conceivable for many applications.