2020
Nanotechnology for catalysis and solar energy conversion
Banin U, Waiskopf N, Hammarstrm L, Boschloo G, Freitag M, Johansson E, S J, Tian H, Johnston M, Herz L, Milot R, Kanatzidis M, Ke W, Spanopoulos I, Kohlstedt K, Schatz G, Lewis N, Meyer T, Nozik A, Beard M, Armstrong F, Megarity C, Schmuttenmaer C, Batista V, Brudvig G. Nanotechnology for catalysis and solar energy conversion. Nanotechnology 2020, 32: 042003. PMID: 33155576, DOI: 10.1088/1361-6528/abbce8.Peer-Reviewed Original ResearchDye-sensitized solar cellsPerovskite solar cellsSolar energy conversionMultiple exciton generationSolar cellsEnergy conversionOrganic photovoltaicsNanoscale characterization methodsNanoscale material characterizationApplication of nanotechnologySolar energy conversion efficiencySolar water splittingConversion efficiencyStructure-property relationshipsNanomaterial synthesisSemiconductor nanoparticlesSingle nanoparticlesScalable manufacturingEnergy conversion efficiencySemiconductor nanostructuresWater splittingFuel conversion efficiencySmart engineeringHybrid halide perovskitesBio-catalysis
2010
Water -stable, hydroxamate anchors for functionalization of TiO 2 surfaces with ultrafast interfacial electron transfer
McNamara W, Milot R, Song H, Snoeberger R, Batista V, Schmuttenmaer C, Brudvig G, Crabtree R. Water -stable, hydroxamate anchors for functionalization of TiO 2 surfaces with ultrafast interfacial electron transfer. Energy & Environmental Science 2010, 3: 917-923. DOI: 10.1039/c001065k.Peer-Reviewed Original ResearchInterfacial electron transferUltrafast interfacial electron transferTiO2 nanoparticlesSolar energy conversionElectron transferPhotocatalytic cellsNanoparticlesOrganic dyesTiO 2 surfaceMetal oxidesEnergy conversionElectron injectionConduction bandTHz spectroscopyAqueous conditionsTiO2Transition metal complexesNeutral pHFunctionalizationMetal complexesCarboxylate anchorStrong bindingStable moleculesOxideCarboxylic acids