Antireflective, photocatalytic, and superhydrophilic coating prepared by facile sparking process for photovoltaic panels

Abstract: Soiling of photovoltaic modules and the reflection of incident light from the solar panel glass reduces the efficiency and performance of solar panels; therefore, the glass should be improved to have antifouling properties. In this work, commercial solar panels were coated with sparked titanium films, and the antireflective, super-hydrophilic, and photocatalytic properties of the films were investigated. The reflectance, photocatalytic properties, and degradation of the organic pollutant methylene blue were de… Show more

“…These two quantities were correlated using the following equation: 𝐸 = ∆𝑉 𝑑 ⁄ , where 𝑑 represents a small perpendicular distance between two equipotential surfaces, and 𝐸 signifies the electric field strength, which remains nearly constant over this limited distance. ∆𝑉 denotes the potential difference between the equipotential surfaces (19,20,27).…”

“…During the operation of the sparking apparatus, the sparking head scanned forward and backward along the X-direction, while the substrate holder moved backward along the Ydirection to coat zinc particles onto the substrate. The material subjected to the process is pure zinc wires (diameter 0.38 mm, purity 99.97%, Advent Research Material Ltd.), which undergo sparking or electron discharge at a breakdown voltage of the insulators (or the medium) (19,20). This results in particles coating the ITO/glass substrate at a spark coating rate of 14.4 mm²/min.…”

“…The objective of this research is to cultivate ZnO nanowalls (NWs) on an indium tin oxide (ITO)/glass substrate or an ITO substrate by utilizing sparking electrodes in an oxygen atmosphere and a magnetic field. The electrical method has been utilized to synthesize nanomaterials such as ZnO nanoparticles, as in the previous works, due to its simplicity (18)(19). The breakdown voltage of the medium between electrodes can be reduced by adding the oxygen atmosphere (20).…”

Zinc Oxide Nanowall Networks Growth on Indium Tin Oxide Substrates in an Oxygen Atmosphere and Magnetic Field via the Sparking Process

“…These two quantities were correlated using the following equation: 𝐸 = ∆𝑉 𝑑 ⁄ , where 𝑑 represents a small perpendicular distance between two equipotential surfaces, and 𝐸 signifies the electric field strength, which remains nearly constant over this limited distance. ∆𝑉 denotes the potential difference between the equipotential surfaces (19,20,27).…”

“…During the operation of the sparking apparatus, the sparking head scanned forward and backward along the X-direction, while the substrate holder moved backward along the Ydirection to coat zinc particles onto the substrate. The material subjected to the process is pure zinc wires (diameter 0.38 mm, purity 99.97%, Advent Research Material Ltd.), which undergo sparking or electron discharge at a breakdown voltage of the insulators (or the medium) (19,20). This results in particles coating the ITO/glass substrate at a spark coating rate of 14.4 mm²/min.…”

“…The objective of this research is to cultivate ZnO nanowalls (NWs) on an indium tin oxide (ITO)/glass substrate or an ITO substrate by utilizing sparking electrodes in an oxygen atmosphere and a magnetic field. The electrical method has been utilized to synthesize nanomaterials such as ZnO nanoparticles, as in the previous works, due to its simplicity (18)(19). The breakdown voltage of the medium between electrodes can be reduced by adding the oxygen atmosphere (20).…”

Zinc Oxide Nanowall Networks Growth on Indium Tin Oxide Substrates in an Oxygen Atmosphere and Magnetic Field via the Sparking Process

“…The absorption peaks were at 655 nm, and the peak intensity decreased regularly with the increase period of exposure. In simpler terms, as the period time increased, the degradation of MB also increased [31]. This implies that the coatings might have self-cleaning properties, potentially removing other organic contaminants from the surface of PV panels.…”

Investigation of an Antireflective Coating System for Solar Cells based on Thin Film Multilayers

CO2 Laser Sintering of TiO2 Nanoparticles Thin Films for Improved Transmittance