The Photocatalytic Window: Photo-Reforming of Organics and Water Splitting for Sustainable Hydrogen Production

Abstract: Precious metal-titania materials make good catalysts for hydrogen production from a variety of organic substrates using sunlight. These substrates essentially act as reductants for water, by intercepting electrophilic oxygen species generated by electron-hole excitation resulting from photon absorption in the titania support. As a result, the hydrogen produced comes partly from water splitting and partly from dehydrogenation of the organic substrate. Why only precious metals work for the reaction is discussed,… Show more

“…Fundamental understanding of these factors, and their individual impact on photocatalytic hydrogen production, still requires considerable work. Sacrificial hole scavengers, such as alcohols, further enhance charge-separation [18][19][20][21][22][23]. Alcohol-photoreforming is energetically facile compared to water splitting, typically affording hydrogen production rates 1-2 orders of magnitude higher than those achieved in pure water.…”

“…Alcohol-photoreforming is energetically facile compared to water splitting, typically affording hydrogen production rates 1-2 orders of magnitude higher than those achieved in pure water. H 2 production rates are strongly dependent on the hole scavenger used (typically primary alcohols, diols or triols) [18][19][20][21][22][23], though little work has been reported examining the effect of alcohol concentration on H 2 production rates.…”

“…Only a limited number of such studies have been reported. Bowker and co-workers [18][19][20][21][22] studied hydrogen production rates over Pd/P25 TiO 2 in different alcohol-water mixtures, and concluded that the presence of a-hydrogens on the alcohol was critical to achieving high H 2 production rates. H 2 production tests using 20 different sacrificial reagents established the reactivity series triols > diols > 2°alcohols > 1°alcohols > 3°alcohols [18].…”

The roles of metal co-catalysts and reaction media in photocatalytic hydrogen production: Performance evaluation of M/TiO2 photocatalysts (M = Pd, Pt, Au) in different alcohol–water mixtures

“…Fundamental understanding of these factors, and their individual impact on photocatalytic hydrogen production, still requires considerable work. Sacrificial hole scavengers, such as alcohols, further enhance charge-separation [18][19][20][21][22][23]. Alcohol-photoreforming is energetically facile compared to water splitting, typically affording hydrogen production rates 1-2 orders of magnitude higher than those achieved in pure water.…”

“…Alcohol-photoreforming is energetically facile compared to water splitting, typically affording hydrogen production rates 1-2 orders of magnitude higher than those achieved in pure water. H 2 production rates are strongly dependent on the hole scavenger used (typically primary alcohols, diols or triols) [18][19][20][21][22][23], though little work has been reported examining the effect of alcohol concentration on H 2 production rates.…”

“…Only a limited number of such studies have been reported. Bowker and co-workers [18][19][20][21][22] studied hydrogen production rates over Pd/P25 TiO 2 in different alcohol-water mixtures, and concluded that the presence of a-hydrogens on the alcohol was critical to achieving high H 2 production rates. H 2 production tests using 20 different sacrificial reagents established the reactivity series triols > diols > 2°alcohols > 1°alcohols > 3°alcohols [18].…”

The roles of metal co-catalysts and reaction media in photocatalytic hydrogen production: Performance evaluation of M/TiO2 photocatalysts (M = Pd, Pt, Au) in different alcohol–water mixtures

“…external diameter) at 45 •C and N 2 was used as a carrier gas (Flow rate of 20mL/min). We, and others, have studied the reaction products during photocatalytic reforming of alcohols which ultimately results in hydrogen and CO 2 formation as the final reaction products [10][11][12][13][14][15].…”

Evidence of Plasmonic Induced Photocatalytic Hydrogen Production on Pd/TiO2 Upon Deposition on Thin Films of Gold

“…It is not clear at all from current literature what the optimum alcohol concentration is for H 2 production in the different M/TiO 2 systems, and whether the optimum concentration varies from alcohol to alcohol (alcohols typically used as sacrificial agents are methanol and ethanol, and to a lesser extent ethylene glycol and glycerol). Bowker and co-workers have made the most important contributions in this area to date [10,[26][27][28][29][30][31][32], reporting hydrogen production rates for the photoreforming of a variety of bio-derivable feedstocks over Pd/P25 and Au/P25 under UV excitation. In the Pd/P25 system, H 2 production rates at an alcohol concentration of 1 vol.% were observed to follow the order triols > diols > 2°alcohols > 1°alcohols > 3°alcohols [26,[28][29][30].…”

Novel Au/TiO2 photocatalysts for hydrogen production in alcohol–water mixtures based on hydrogen titanate nanotube precursors