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Multifunctional Coatings

Okada, M., Yamada, Y., Jin, P., Tazawa, M., and Yoshimura, K., Fabrication of multifunctional coating which combines low-e property and visible-light-responsive photocatalytic activity, Thin Solid Films, 442,217,2003. [Pg.280]

Multidentate V-heterocyclic ligands, thorium and, 24 767 Multidimensional gas chromatography, 4 617-618 6 433-434 Multidrug resistant bacteria, 18 252 Multi-effect distillation (ME), 26 65—67 Multi-effect vapor-compression submerged-tube desalination plant, 26 70 Multielevation piperacks, 19 515 Multifeed fractionation, 10 616 Multifilamentary superconductor, 23 846 Multifilament sutures, 24 218 threads for, 24 207 Multifilament yarns, 11 177-178 Multifile patent searches, 18 244 Multifunctional aliphatic epoxies, 10 376 Multifunctional coatings, 1 714-716 Multifunctional epoxy resins, 10 367-373, 418, 454... [Pg.605]

Lee H, Dellatore SM, Miller WM, Messersmith PB. Mussel-inspired surface chemistry for multifunctional coatings. Science 2007 318 426-430. [Pg.255]

Electrodeposition of PANI derivatives was achieved by Shah and Iroh [108] in the case of Al alloy (2024) and N-ethylaniline in aqueous oxalic acid solution. The coating was electrodeposited by cyclic voltammetry by application of an unusually large potential range (-1V to -I-3V/SCE). Corrosion current was measured in chloride solutions from Tafel plots and was found to be significantly lower (about one order of magnitude) than that of bare Al-2024. Multifunctional coatings (PPy/PANI) were also achieved on aluminium by coelectropolymerization of aniline and pyrrole (in a feed ratio of 3 7) in oxalic acid solution, but protection performances were not given [109,110]. [Pg.660]

Iroh, J.O., et al. 2003. Electrochemical synthesis A novel technique for processing multifunctional coatings. Prog Org Coat 47 (3—4) 365. [Pg.1646]

Other multifunctional coating [106] develops transparent superhydrophobic surfaces. Trimethylsiloxane (TMS) surface-functionalized silica nanoparticles embedded in an organosihca gel matrix were used to obtain the films, which present appropriate roughness and low surface energy without any additional hydrophobic capping layer. The amount of nanoparticles and silica gel binder determine water repellence and the thermomechanical stability of the coated surfaces. [Pg.924]

The field of applications of multifunctional coatings runs from glass to tiles or textiles, combining the photocatalytic, self-cleaning, UV protective, and antimicrobial properties of Ti02 with the antimicrobial activity of Ag. [Pg.925]

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