Multifunctional Antireflection Coatings Based on Novel Hollow Silica–Silica Nanocomposites

Abstract: Antireflection (AR) coatings that exhibit multifunctional characteristics, including high transparency, robust resistance to moisture, high hardness, and antifogging properties, were developed based on hollow silica-silica nanocomposites. These novel nanocomposite coatings with a closed-pore structure, consisting of hollow silica nanospheres (HSNs) infiltrated with an acid-catalyzed silica sol (ACSS), were fabricated using a low-cost sol-gel dip-coating method. The refractive index of the nanocomposite coating… Show more

“…Honestly, the low transmittance and high reflectance of the thin film in 400~600 nm are the disadvantages for the practical application in solar cells, which may due to the light scattering by the nipples and the large thickness of the thin film 26,27 . Furthermore, the refractive index of the moth-eye thin film was estimated by Equation 1 18 , and it is 1.319, which is a little higher than the refractive index (1.22) of optimal single-layer antireflective thin films on commercial glass 18,28 .Where, r is the reflectance of one side of thin film, n s , n air and n are the refractive index of the substrate, air and film, respectively. In fact, the moth-eye thin film has a gradient refractive index, which endows the coated glass with a low reflection (2.8%).…”

In situ formation of artificial moth-eye structure by spontaneous nano-phase separation

“…Honestly, the low transmittance and high reflectance of the thin film in 400~600 nm are the disadvantages for the practical application in solar cells, which may due to the light scattering by the nipples and the large thickness of the thin film 26,27 . Furthermore, the refractive index of the moth-eye thin film was estimated by Equation 1 18 , and it is 1.319, which is a little higher than the refractive index (1.22) of optimal single-layer antireflective thin films on commercial glass 18,28 .Where, r is the reflectance of one side of thin film, n s , n air and n are the refractive index of the substrate, air and film, respectively. In fact, the moth-eye thin film has a gradient refractive index, which endows the coated glass with a low reflection (2.8%).…”

In situ formation of artificial moth-eye structure by spontaneous nano-phase separation

“…10 Therefore, the AR thin films on solar glass must be able to resist external weathering, including moisture, rain and high temperatures. Typically, the solar glass used in PV modules usually encounters constant temperature between 21°C and 53°C during operation.…”

“…10,48 Mechanical properties of SiO 2 &TiO 2 DSHN thin films The corrosion takes place in two steps: (1) H + of water in the form of H 3 O + first diffuses into the glass and exchanges with cations, leading to a hydrated layer; (2) Si-O-Si bridging bonds are subsequently hydrated, breaking up the network and forming a gel, which leads to network dissolution.…”

“…[1][2][3][4][5][6] There would be no reflection if there is a destructive interference between the light reflected from the film-substrate and the air-film interfaces. [7][8][9][10][11] Among them hollow SiO 2 nanoparticles have been proved to be good building blocks for AR thin films because the inner cavity of the SiO 2 nanoparticles offers a large volume for tuning the RI of the AR thin films. 22.…”

Fabrication of mechanically robust, self-cleaning and optically high-performance hybrid thin films by SiO₂&TiO₂double-shelled hollow nanospheres

“…The surface properties of the materials can be changed by coating application or surface modification, to create the desired anti-adhesion characteristics without altering the bulk properties of materials. Various coatings have been developed in order to achieve a variety of functional characteristics, including anti-scratch, anti-reflective, anti-fogging, anti-microbial or self-cleaning properties (Türetgen et al, 2012;Ovissipour et al, 2014;Zhang et al, 2014). Attempts have been made to reduce biofilm formation by coating surfaces with antimicrobials, by the incorporation of antimicrobial products into surface materials or by modifying the surface's physicochemical properties (Hetrick et al, 2009;Bruellhoff et al, 2010;Simoes et al, 2010.…”

Reduction of microbial biofilm formation using hydrophobic nano-silica coating on cooling tower fill material