2016
DOI: 10.1073/pnas.1609374113
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Carrier dynamics and the role of surface defects: Designing a photocatalyst for gas-phase CO 2 reduction

Abstract: In 2 O 3-x (OH) y nanoparticles have been shown to function as an effective gas-phase photocatalyst for the reduction of CO 2 to CO via the reverse water-gas shift reaction. Their photocatalytic activity is strongly correlated to the number of oxygen vacancy and hydroxide defects present in the system. To better understand how such defects interact with photogenerated electrons and holes in these materials, we have studied the relaxation dynamics of In 2 O 3-x (OH) y nanoparticles with varying concentration of… Show more

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Cited by 101 publications
(74 citation statements)
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“…These results have implications for the design of In 2 O 3 based materials optoelectronic applications: Although the ubiquitous hydrogen species and adsorbed OH/oxygen groups do not affect the surface conductivity, their presence may have a strong influence on the optical transparency. In addition, while an n ‐type surface can be unwanted for a particular electronic application, it clearly proves to be beneficial in photocatalysis, enabling the reverse water‐gas‐shift and methanol production reactions . This appears to be particularly relevant for oxygen defect rich In 2 O 3 with nanometer scale particles with high surface to volume ratios .…”
Section: Resultsmentioning
confidence: 99%
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“…These results have implications for the design of In 2 O 3 based materials optoelectronic applications: Although the ubiquitous hydrogen species and adsorbed OH/oxygen groups do not affect the surface conductivity, their presence may have a strong influence on the optical transparency. In addition, while an n ‐type surface can be unwanted for a particular electronic application, it clearly proves to be beneficial in photocatalysis, enabling the reverse water‐gas‐shift and methanol production reactions . This appears to be particularly relevant for oxygen defect rich In 2 O 3 with nanometer scale particles with high surface to volume ratios .…”
Section: Resultsmentioning
confidence: 99%
“…In unison with other extrinsic donor‐type defects like interstitial hydrogen, ubiquitously incorporated into the crystal lattice, these states push the E F toward the CNL and produce a 2D gas of itinerant electrons (2DEG) near the surface . Remarkably, theory and experimental studies also reveal the important impact of these surface defects in promoting the reverse water‐gas‐shift reaction . At the (111) surface, in particular, adsorbed OH groups couple with indium sites proximal to an oxygen vacancy, forming a frustrated Lewis pair.…”
Section: Introductionmentioning
confidence: 99%
“…[129] Das Ersetzen der ZnO-Trägers durch TiO 2 oder Abbildung 8. [123] Copyright 2016, National Academyo fSciences. a) Wirkung der Vorstufenverbindung auf die photokatalytische Leistungsfähigkeit.…”
Section: Lichtgetriebene Umgekehrte Wassergas-shift-reaktionunclassified
“…Abbildung 7. a) Zeitprofil des CO-Verbrauchs, der CO 2 -Entwicklung und der H 2 -Entwicklung über einem Au/TiO 2 -Katalysator (1 Gew.-%) unter Sonnenlichtbestrahlung. Ferner wurde durch transiente Femtosekunden-Absorptionsmessungen nachgewiesen, dass Sauerstofffehlstellen und Oberflächen-Hydroxygruppen eine wesentliche Rolle bei den Ladungsrelaxationswegen des angeregten Zustands spielen, die stark mit der photokatalytischen Aktivitätkorrelieren [123]. GenehmigteW iedergabe [105].…”
unclassified
“…Such engineering aims at controlling the type and distribution of defects, which can govern the chemical reactivity of the metal oxide toward CO 2 regardless of the type of energy used to activate the process. For example, in photocatalytic CO 2 reduction, oxygen vacancies and hydroxyl radicals can trap the charge carriers (electrons and holes), thus retarding recombination . Alternatively, specific defect types (in specific metal oxides) can drive the formation of low energy midgap states of the metal oxide in its photoinduced excited state, creating surface frustrated Lewis pairs (FLPs) with increased Lewis acidity and basicity that are responsible for enhanced CO 2 hydrogenation…”
Section: The Double Impact Of Co2 Reduction: the Energy Cycle With A mentioning
confidence: 99%