Synthesis and Application of Titanium Oxide Nanohole Arrays
Identifieur interne : 000001 ( Main/Exploration ); précédent : 000000; suivant : 000002Synthesis and Application of Titanium Oxide Nanohole Arrays
Auteurs : RBID : ISTEX:978-3-642-03622-4_Chapter_5.pdfAbstract
A titania nanohole array, consisting of an assembly of titania tubes with inner diameters of 200 nm and wall thicknesses of 30 nm, was successfully prepared by a liquid phase deposition method. Heat treatment at 900°C results in a titania nanohole array that consists of highly crystalline anatase and has good photocatalytic properties. It was found that dissolution of anodic alumina and the deposition of titania took place simultaneously, and alumina functioned as the nanostructure template as well as a fluoride ion scavenger. A titania nanohole array with one end closed was used as a positive electrode for a lithium ion battery, in which an electric capacity close to 300 mAh/g was obtained. In addition to titania, this preparation method is applicable to various oxides such as tin oxide, zirconium oxide, indium oxide, and iron oxide.
DOI: 10.1007/978-3-642-03622-4_5
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Heat treatment at 900°C results in a titania nanohole array that consists of highly crystalline anatase and has good photocatalytic properties. It was found that dissolution of anodic alumina and the deposition of titania took place simultaneously, and alumina functioned as the nanostructure template as well as a fluoride ion scavenger. A titania nanohole array with one end closed was used as a positive electrode for a lithium ion battery, in which an electric capacity close to 300 mAh/g was obtained. In addition to titania, this preparation method is applicable to various oxides such as tin oxide, zirconium oxide, indium oxide, and iron oxide.</div></front></TEI><mods xsi:schemaLocation="http://www.loc.gov/mods/v3 file:///applis/istex/home/loadistex/home/etc/xsd/mods.xsd" version="3.4" istexId="6ae9309b215c21b606057f940c6b54943b40bc16"><titleInfo lang="eng"><title>Synthesis and Application of Titanium Oxide Nanohole Arrays</title></titleInfo><name type="personal"><namePart type="given">Shinsuke</namePart><namePart type="family">Yamanaka</namePart><role><roleTerm type="text">author</roleTerm></role><description>Yamanak@see.eng.osaka-u.ac.jp</description><affiliation>Division of Sustainable Energy and Environmental Engineering, Graduate School of Engineering, Osaka University, 565-0871, Osaka, Suita, Japan</affiliation></name><name type="personal"><namePart type="given">Masayoshi</namePart><namePart type="family">Uno</namePart><role><roleTerm type="text">author</roleTerm></role><description>uno@u-fukui.ac.jp</description><affiliation>Research Institute of Nuclear Engineering, University of Fukui, 910-8507, Fukui-city, Fukui, Japan</affiliation></name><typeOfResource>text</typeOfResource><genre>Original Paper</genre><originInfo><publisher>Springer Berlin Heidelberg, Berlin, Heidelberg</publisher><copyrightDate encoding="w3cdtf">2010</copyrightDate></originInfo><language><languageTerm type="code" authority="iso639-2b">eng</languageTerm></language><physicalDescription><internetMediaType>text/html</internetMediaType></physicalDescription><abstract lang="eng">A titania nanohole array, consisting of an assembly of titania tubes with inner diameters of 200 nm and wall thicknesses of 30 nm, was successfully prepared by a liquid phase deposition method. Heat treatment at 900°C results in a titania nanohole array that consists of highly crystalline anatase and has good photocatalytic properties. It was found that dissolution of anodic alumina and the deposition of titania took place simultaneously, and alumina functioned as the nanostructure template as well as a fluoride ion scavenger. A titania nanohole array with one end closed was used as a positive electrode for a lithium ion battery, in which an electric capacity close to 300 mAh/g was obtained. In addition to titania, this preparation method is applicable to various oxides such as tin oxide, zirconium oxide, indium oxide, and iron oxide.</abstract><relatedItem type="series"><titleInfo><title>Topics in Applied Physics</title><subTitle>Recent Technologies and Applications</subTitle><partNumber>Year: 2010</partNumber><partNumber>Volume: 117</partNumber><partName lang="eng">Inorganic and Metallic Nanotubular Materials [Recent Technologies and Applications]</partName></titleInfo><genre>Monograph</genre><genre>eBook</genre><originInfo><copyrightDate encoding="w3cdtf">2010</copyrightDate><issuance>monographic</issuance></originInfo><subject usage="primary"><topic>Materials Science</topic><topic>Nanotechnology</topic><topic>Metallic Materials</topic><topic>Solid State Physics</topic><topic>Spectroscopy and Microscopy</topic><topic>Engineering, general</topic></subject><identifier type="issn">0303-4216</identifier><identifier type="isbn">978-3-642-03620-0</identifier><identifier type="isbn">Electronic: 978-3-642-03622-4</identifier><identifier type="doi">10.1007/978-3-642-03622-4</identifier><identifier type="matrixNumber">560</identifier><identifier type="local">BookChapterCount: 20</identifier><identifier type="local">BookTitleID: 183468</identifier><recordInfo><recordOrigin>Springer-Verlag Berlin Heidelberg, 2010</recordOrigin></recordInfo></relatedItem><identifier type="doi">10.1007/978-3-642-03622-4_5</identifier><identifier type="matrixNumber">Chap5</identifier><identifier type="local">5</identifier><part><extent unit="pages"><start>59</start><end>71</end></extent></part><recordInfo><recordOrigin>Springer-Verlag Berlin Heidelberg, 2010</recordOrigin><recordIdentifier>978-3-642-03622-4_Chapter_5.pdf</recordIdentifier></recordInfo></mods></record>Pour manipuler ce document sous Unix (Dilib)
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