TY - JOUR

T1 - Photocatalytic H-2 Evolution from Oxalic Acid

T2 - Effect of Cocatalysts and Carbon Dioxide Radical Anion on the Surface Charge Transfer Mechanisms

AU - AlSalka, Yamen

AU - Al-Madanat, Osama

AU - Curti, Mariano

AU - Hakki, Amer

AU - Bahnemann, Detlef W.

N1 - Funding Information: Yamen AlSalka gratefully acknowledges the financial support from the Deutscher Akademischer Austauschdienst (DAAD) together with the Federal Foreign Office in Germany. Osama Al-Madanat gratefully acknowledges the financial support from the Katholischer Akademischer Ausländer-Dienst (KAAD). Mariano Curti is grateful to the DAAD together with the Ministerio de Educación, Cultura, Ciencia y Tecnología (Argentina) for his ALEARG scholarship. This work was supported by Saint-Petersburg State University via a research grant ID 32706707. The Institute of Physical Chemistry and Electrochemistry at Hannover University is acknowledged for the TEM and XRD measurements. The Institut for Mineralogie at Hannover University is acknowledged for the ICP-OES measurements. The Institute of Solid State Physics at Hannover University is acknowledged for the XPS measurements. Publisher Copyright: Copyright © 2020 American Chemical Society.

PY - 2020/7/27

Y1 - 2020/7/27

N2 - Photocatalytic reforming of carboxylic acids on cocatalyst-loaded semiconductors is an attractive process for H-2 generation that has been studied for years. Experimental support for the surface reaction mechanisms, nevertheless, is still insufficient. Herein, the mechanism of the photocatalytic conversion of oxalic acid in anaerobic conditions together with the total yields have been deeply investigated by employing self-prepared TiO2 photocatalysts loaded with different noble metals (Pt and/or Au). While the photocatalytic H-2 evolution remarkably occurs over bare TiO2, the loading with a cocatalyst significantly boosts the activity. Pt/TiO2 shows higher photonic efficiencies than Au/TiO2, whereas Au-Pt/TiO2 has no additional advantage. The turnover numbers (TONs) of complete degradation have been calculated as 4.86 and 12.14 over bare TiO2 and noble-metals/TiO2, respectively, confirming true photocatalytic processes. The degradation of oxalic acid has been experimentally confirmed to proceed via the photo-Kolbe reaction, forming (CO2-)-C-center dot radicals. The contribution of the current-doubling mechanism and the effect of the disproportionation reaction of radicals on the total yield is discussed, showing a loss of efficiency due to secondary reactions. A remarkable diversion of H-2 evolution was recorded in all cases with Pt/TiO2 showing an similar to 30% decrease in the evolved amounts of H-2 with respect to the theoretically expected amount. This diversion can be attributed to (i) the increase in charge carrier recombination due to oxalic acid consumption, (ii) the incomplete scavenging of the photogenerated electrons by Pt nanoparticles as proved by solid-phase EPR spectroscopy, (iii) the formation of byproducts depending on the nature of the cocatalyst, and (iv) the disproportionation of (CO2-)-C-center dot radicals, which reduces the contribution of the current doubling. Formate and formaldehyde have been experimentally detected, and EPR spin-trap experiments confirm a surface charge transfer mechanism through the TiO2/oxalic acid interface. This work helps in closing the gap of knowledge between the theoretical and experimental aspects.

AB - Photocatalytic reforming of carboxylic acids on cocatalyst-loaded semiconductors is an attractive process for H-2 generation that has been studied for years. Experimental support for the surface reaction mechanisms, nevertheless, is still insufficient. Herein, the mechanism of the photocatalytic conversion of oxalic acid in anaerobic conditions together with the total yields have been deeply investigated by employing self-prepared TiO2 photocatalysts loaded with different noble metals (Pt and/or Au). While the photocatalytic H-2 evolution remarkably occurs over bare TiO2, the loading with a cocatalyst significantly boosts the activity. Pt/TiO2 shows higher photonic efficiencies than Au/TiO2, whereas Au-Pt/TiO2 has no additional advantage. The turnover numbers (TONs) of complete degradation have been calculated as 4.86 and 12.14 over bare TiO2 and noble-metals/TiO2, respectively, confirming true photocatalytic processes. The degradation of oxalic acid has been experimentally confirmed to proceed via the photo-Kolbe reaction, forming (CO2-)-C-center dot radicals. The contribution of the current-doubling mechanism and the effect of the disproportionation reaction of radicals on the total yield is discussed, showing a loss of efficiency due to secondary reactions. A remarkable diversion of H-2 evolution was recorded in all cases with Pt/TiO2 showing an similar to 30% decrease in the evolved amounts of H-2 with respect to the theoretically expected amount. This diversion can be attributed to (i) the increase in charge carrier recombination due to oxalic acid consumption, (ii) the incomplete scavenging of the photogenerated electrons by Pt nanoparticles as proved by solid-phase EPR spectroscopy, (iii) the formation of byproducts depending on the nature of the cocatalyst, and (iv) the disproportionation of (CO2-)-C-center dot radicals, which reduces the contribution of the current doubling. Formate and formaldehyde have been experimentally detected, and EPR spin-trap experiments confirm a surface charge transfer mechanism through the TiO2/oxalic acid interface. This work helps in closing the gap of knowledge between the theoretical and experimental aspects.

KW - photocatalysis

KW - photoreforming

KW - oxalic acid

KW - H-2 production

KW - carbon dioxide radical anion

KW - TiO2

KW - ELECTRON-PARAMAGNETIC-RES

KW - TITANIUM-DIOXIDE

KW - TIO2 PHOTOCATALYSIS

KW - HYDROGEN-PRODUCTION

KW - ORGANIC-COMPOUNDS

KW - AQUEOUS-SOLUTION

KW - PLATINIZED TIO2

KW - HOLE TRANSFER

KW - DEGRADATION

KW - NANOPARTICLES

KW - H production

KW - TiO

KW - H2production

UR - http://www.scopus.com/inward/record.url?scp=85090999159&partnerID=8YFLogxK

UR - https://www.mendeley.com/catalogue/a0cafeb7-0df1-3e71-b05e-dd19b9693d44/

U2 - 10.1021/acsaem.0c00826

DO - 10.1021/acsaem.0c00826

M3 - статья

VL - 3

SP - 6678

EP - 6691

JO - ACS Applied Energy Materials

JF - ACS Applied Energy Materials

SN - 2574-0962

IS - 7

ER -