MARC Record from marc_columbia

LEADER: 10447cam a2200517 a 4500
001 7932677
005 20221201045323.0
008 100607s2010 flua b 001 0 eng
010 $a 2010020849
015 $aGBB033760$2bnb
016 7 $a015500033$2Uk
016 7 $a015541420$2Uk
019 $a232981617
020 $a9781420093933
020 $a1420093932
020 $a1420094351 (series)
020 $a9781420094350 (series)
029 1 $aCDX$b8482125
029 1 $aDEBBG$bBV036090650
029 1 $aAU@$b000045671226
035 $a(OCoLC)ocn232981626
035 $a(OCoLC)232981626$z(OCoLC)232981617
035 $a(NNC)7932677
035 $a7932677
040 $aDLC$cDLC$dUKM$dBTCTA$dYDXCP$dCDX$dPIT$dOrLoB-B
050 00 $aTA418.9.C57$bZ48 2010
050 4 $aTA418.9.T45$bO73 2010
082 00 $a621.3815/2$222
245 00 $aOrganic nanostructured thin film devices and coatings for clean energy /$cedited by Sam Zhang.
246 1 $iAt head of title:$aHandbook of nanostructured thin films and coatings
260 $aBoca Raton :$bCRC Press,$c2010.
263 $a1006
300 $axi, 241 pages :$billustrations ;$c26 cm
336 $atext$btxt$2rdacontent
337 $aunmediated$bn$2rdamedia
504 $aIncludes bibliographical references and index.
505 00 $g1.$tThin Film Solar Cells Based on the Use of Polycrystalline Thin Film Materials /$rI. Forbes -- $g1.1.$tIntroduction -- $g1.2.$tThin Film Solar Cells Based on the Use of CdTe -- $g1.2.1.$tHistorical Development of CdTe Solar Cells -- $g1.2.2.$tMaterial Properties -- $g1.2.3.$tDeposition Techniques for CdTe -- $g1.2.3.1.$tThermal Evaporation -- $g1.2.3.2.$tSputtering -- $g1.2.3.3.$tClose-Spaced Sublimation -- $g1.2.3.4.$tVapor Transport Deposition -- $g1.2.3.5.$tElectrodeposition -- $g1.2.3.6.$tMetal-Organic Chemical Vapor Deposition -- $g1.2.3.7.$tSpray Pyrolysis -- $g1.2.3.8.$tScreen Printing -- $g1.2.3.9.$tAtomic Layer Epitaxy -- $g1.2.4.$tSolar Cell Structure, Formation, and Properties -- $g1.2.4.1.$tSubstrate -- $g1.2.4.2.$tTransparent Conductive Oxide -- $g1.2.4.3.$tBuffer Layer -- $g1.2.4.4.$tAbsorber -- $g1.2.4.5.$tCdCl2 Heat Treatment -- $g1.2.4.6.$tBack Contact -- $g1.2.5.$tState-of-the-Art CdTe PV Devices and Modules -- $g1.3.$tThin Film Solar Cells Based on the Use of Chalcopyrite Compounds -- $g1.3.1.$tHistorical Development of CuInGaSe2 Solar Cells -- $g1.3.2.$tChoice of Device Configuration, Substrate, and Back-Contact Material -- $g1.3.3.$tThin Film Deposition Using the Co-Evaporation Method -- $g1.3.4.$tThin Film Synthesis Using Selenization (or Sulfidization) of Pre-Deposited Precursor Layers -- $g1.3.5.$tDevelopment of CuInS2 Solar Cells -- $g1.3.6.$tState-of-the-Art Chalcopyrite PV Devices and Modules -- $g1.3.6.1.$tWurth Solar Process -- $g1.3.6.2.$tAvancis GmbH & Co. KG -- $g1.3.6.3.$tShowa Shell -- $g1.3.6.4.$tSolarion AG/Photovoltaics -- $g1.3.6.5.$tNanosolar, Inc -- $g1.3.6.6.$tHelioVolt Corporation -- $g1.3.6.7.$tSolyndra, Inc -- $g1.3.6.8.$tHonda Soltec Co., Ltd -- $g1.3.6.9.$tSolibro GmbH -- $g1.3.6.10.$tSulfurcell Solartechnik GmbH -- $g1.3.6.11.$tOdersun AG -- $g1.3.6.12.$tGlobal Solar Energy, Inc -- $g1.3.6.13.$tCIS Solartechnik GmbH & Co. KG -- $g1.4.$tNovel Absorber Layers -- $g1.4.1.$tCuInAlSe2 -- $g1.4.2.$tCu2ZnSnS4 and Cu2ZnSnSe4 -- $g1.4.3.$tSnS -- $g1.5.$tNovel Buffer Layers -- $g1.5.1.$tBuffer Layer Requirements -- $g1.5.2.$tDeposition Techniques -- $g1.5.2.1.$tChemical Bath Deposition -- $g1.5.2.2.$tThermal Evaporation Method -- $g1.5.2.3.$tSputtering -- $g1.5.2.4.$tSpray Pyrolysis -- $g1.5.2.5.$tElectrodeposition -- $g1.5.2.6.$tAtomic Layer Epitaxy -- $g1.5.2.7.$tMOCVD -- $g1.5.2.8.$tILGAR -- $g1.5.3.$tCadmium-Based Materials -- $g1.5.4.$tIndium-Based Materials -- $g1.5.5.$tZinc-Based Materials -- $g1.6.$tTransparent Conducting Oxides -- $g1.6.1.$tIntroduction -- $g1.6.2.$tTin Oxide -- $g1.6.3.$tZinc Oxide -- $g1.6.4.$tCadmium Oxide -- $g1.6.5.$tCadmium Stannate and Zinc Stannate -- $g1.6.6.$tp-Type Transparent Conducting Oxides -- $g1.7.$tFuture Issues and Prospects of Thin Film Photovoltaics -- $tAcknowledgment -- $tAbbreviations -- $tSymbols -- $tReferences -- $g2.$tAnodized Titania Nanotube Array and Its Application in Dye-Sensitized Solar Cells /$rXiaodong He -- $g2.1.$tAnodized Titania Nanotube Array -- $g2.1.1.$tElectrochemical Anodization -- $g2.1.2.$tTitania Nanotube Growth Mechanism -- $g2.1.3.$tControl of the Geometry of the Anodized Titania Nanotube Arrays -- $g2.1.3.1.$tEffect of Applied Potential and Working Distance -- $g2.1.3.2.$tEffect of Electrolyte Composition and pH Value -- $g2.1.3.3.$tEffect of Temperature and Stirring -- $g2.2.$tApplication in Dye-Sensitized Solar Cells -- $g2.2.1.$tIntroduction -- $g2.2.2.$tTypical Structure and Working Principle of Dye-Sensitized Solar Cells -- $g2.2.3.$tEfficiency Limiting Factors of Dye-Sensitized Solar Cells -- $g2.2.4.$tFrom Nanoparticle Network to Nanotube Array-Based Photoanode -- $g2.2.5.$tEffect of TiO2 Nanotube Geometries on the Performance of Dye-Sensitized Solar Cells -- $g2.2.5.1.$tEffect of Wall Thickness -- $g2.2.5.2.$tEffect of Length -- $g2.2.5.3.$tEffect of Pore Diameter and Intertube Spacing -- $g2.2.5.4.$tSummary -- $g2.2.6.$tThe Challenge -- $tAbbreviations -- $tSymbols -- $tReferences -- $g3.$tProgress and Challenges of Photovoltaic Applications of Silicon Nanocrystalline Materials /$rJatin K. Rath -- $g3.1.$tIntroduction -- $g3.2.$tDeposition of Nanocrystalline Silicon -- $g3.2.1.$tGrowth Process -- $g3.2.2.$tDeposition Techniques -- $g3.3.$tMaterial Characterization -- $g3.3.1.$tnc-Si Material Characteristics -- $g3.3.1.1.$tStructure -- $g3.3.1.2.$tElectronic Characteristics -- $g3.3.2.$tCharacterization Techniques -- $g3.3.2.1.$tStructure -- $g3.3.2.2.$tDensity of States -- $g3.4.$tSolar Cell Devices -- $g3.4.1.$tOn Glass Substrates -- $g3.4.2.$tOn Flexible Substrates -- $g3.5.$tConclusion -- $tReferences -- $g4.$tSemiconductive Nanocomposite Films for Clean Environment /$rJoe H. Hsieh -- $g4.1.$tNanocomposite Thin Films -- $g4.1.1.$tNanocrystalline Materials -- $g4.1.2.$tMetal Nanoparticles -- $g4.1.3.$tNanocomposite Materials -- $g4.1.4.$tSynthesis of Nanocomposite Films -- $g4.2.$tApplication in Water Splitting -- $g4.2.1.$tProgress on Electrode Materials -- $g4.2.1.1.$tTiO2 -- $g4.2.1.2.$tVisible-Light Photocatalytic Materials -- $g4.2.2.$tEnhanced Efficiency by Nanocomposites -- $g4.2.2.1.$tMetal-Semiconductor Nanocomposites -- $g4.2.2.2.$tSemiconductor Nanocomposites -- $g4.3.$tApplication in Bactericide and Water Disinfection -- $g4.3.1.$tBacteria -- $g4.3.2.$tAntibacterial Materials -- $g4.3.3.$tApplications of Antibacterial Materials -- $g4.3.4.$tMechanisms of Bactericide -- $g4.3.4.1.$tBactericide by Metal Ions -- $g4.3.4.2.$tBactericide by Photocatalysis -- $g4.3.5.$tNanocomposite Thin Films for Bactericide -- $g4.3.5.1.$tEnhanced Dissolution of Metal Ions -- $g4.3.5.2.$tMetal-Ceramic Nanocomposites -- $g4.3.5.3.$tMetal-Photocatalyst Nanocomposites -- $g4.3.5.4.$tSemiconductor-Semiconductor Nanocomposites -- $g4.4.$tSummary and Recent Developments -- $tReferences -- $g5.$tThin Coating Technologies and Applications in High-Temperature Solid Oxide Fuel Cells /$rSan Ping Jiang -- $g5.1.$tIntroduction -- $g5.2.$tChemical Deposition Methods -- $g5.2.1.$tChemical Vapor Deposition and Atomic Layer Deposition -- $g5.2.2.$tElectrochemical Vapor Deposition -- $g5.3.$tPhysical Deposition Techniques -- $g5.3.1.$tMagnetron Sputtering Techniques -- $g5.3.2.$tPulse Laser Deposition -- $g5.3.3.$tPlasma Spray Deposition -- $g5.4.$tColloidal and Ceramic Powder Techniques -- $g5.4.1.$tColloidal Techniques -- $g5.4.1.1.$tSlurry-Coating, Spin-Coating, and Dip-Coating Methods -- $g5.4.1.2.$tSol-Gel Method -- $g5.4.1.3.$tScreen-Printing Method -- $g5.4.1.4.$tElectrophoretic Deposition -- $g5.4.2.$tCeramic Powder Techniques -- $g5.4.2.1.$tTape-Casting and Freeze-Tape-Casting Processes -- $g5.4.2.2.$tTape-Calendering Process -- $g5.4.2.3.$tDry-Pressing Method -- $g5.5.$tFlame-Assisted Colloidal Process -- $g5.5.1.$tSpray Pyrolysis and Flame-Assisted Vapor Deposition -- $g5.5.2.$tElectrostatic Spray Deposition -- $g5.6.$tLithography and Etching Techniques for μ-SOFCs -- $g5.7.$tConcluding Remarks -- $tAbbreviations -- $tReferences -- $g6.$tNanoscale Organic Molecular Thin Films for Information Memory Applications /$rY.L. Song -- $g6.1.$tIntroduction -- $g6.2.$tActive Layer Growth, Device Fabrication, and Switching Mechanism -- $g6.2.1.$tActive Layer Growth -- $g6.2.1.1.$tVacuum Thermal Vapor Deposition -- $g6.2.1.2.$tSelf-Assembly Monolayer -- $g6.2.1.3.$tLangmuir-Blodgett Monolayers -- $g6.2.1.4.$tVacuum Spray Deposition -- $g6.2.1.5.$tSpin Coating and Dip Coating -- $g6.2.2.$tDevice Fabrication -- $g6.2.2.1.$tPreparations of Substrate and Electrode -- $g6.2.2.2.$tMolecular Materials -- $g6.2.2.3.$tApproaches for Molecular Junction Fabrication -- $g6.2.2.4.$tDevice Characterizations -- $g6.2.3.$tSwitching Mechanisms -- $g6.3.$tRedox-Molecule-Based Memory -- $g6.3.1.$tCharge Carrier Injection and Transport -- $g6.3.2.$tRedox Materials, Thin Film, and Property -- $g6.3.3.$tInterfaces between Redox Molecular Film and Electrode -- $g6.3.4.$tMolecular Switching and Memory -- $g6.4.$tSelf-Assembly Monolayer-Based Memory -- $g6.4.1.$tSelf-Assembly Monolayer and Property -- $g6.4.1.1.$tCharge Transport in Molecular Monolayer Junctions -- $g6.4.1.2.$tThiolated Self-Assembly Monolayers --
505 80 $g6.4.1.3.$tOrganosilane-Based Self-Assembly Monolayers -- $g6.4.2.$tMolecular Switching and Memory -- $g6.4.2.1.$tPatterning Self-Assembly Monolayers -- $g6.4.2.2.$tSwitching of Self-Assembly Monolayer Devices -- $g6.5.$tOther Organic-Materials-Based Memory -- $g6.6.$tSummary and Outlooks -- $tAcknowledgments -- $tAbbreviations -- $tSymbols -- $tReferences.
650 0 $aThin films.$0http://id.loc.gov/authorities/subjects/sh85134864
650 0 $aCoatings.$0http://id.loc.gov/authorities/subjects/sh85027504
650 0 $aNanostructured materials.$0http://id.loc.gov/authorities/subjects/sh93000864
650 0 $aSolar cells.$0http://id.loc.gov/authorities/subjects/sh85124492
650 0 $aGreen technology.$0http://id.loc.gov/authorities/subjects/sh94001791
650 0 $aComputer storage devices.$0http://id.loc.gov/authorities/subjects/sh85029541
700 1 $aZhang, Sam.$0http://id.loc.gov/authorities/names/no2007158926
852 00 $boff,eng$hTA418.9.C57$iZ48 2010g