Hydrogen production by photocatalytic steam reforming of methanol on noble metal-modified TiO2

The photocatalytic production of hydrogen by methanol steam reforming was studied over a series of pristine or noble metal (Ag, Au, Au–Ag alloy and Pt) – modified TiO2 photocatalysts, synthesised by flame spray pyrolysis or by the deposition of preformed noble metal nanoparticles on TiO2. A closed recirculation apparatus was employed, with the photocatalyst bed continuously fed with methanol/water vapours. Methanol underwent oxidation up to CO2 through the formation of formaldehyde and formic acid. Carbon monoxide, methane, methyl formate, acetaldehyde and dimethyl ether were identified as side products. Hydrogen evolved at constant rate, which significantly increased upon noble metal addition, Pt being the most effective co-catalyst, followed by gold and silver, according to their work function values. A systematic investigation into the effects of the inlet gas composition gave valuable information on the prevailing reaction paths and on the conditions of process optimisation, also in terms of distribution of CH3OH oxidation products.

The rate of photocatalytic hydrogen production rH2rH2 from methanol/water vapours over noble metal (NB) – modified TiO2 and the selectivity to different methanol oxidation products were found to correlate with the NB work function and with NB particles’ size and dispersion. They sensibly varied with the H2O/CH3OH molar ratio in the gas-phase reactants mixture.Figure optionsDownload high-quality image (67 K)Download as PowerPoint slide