Trocino, Stefano, Lo Vecchio, Carmelo, Zignani, Sabrina Campagna, Carbone, Alessandra, Saccà, Ada, Baglio, Vincenzo, Gómez, Roberto, Aricò, Antonino Salvatore
Dry Hydrogen Production in a Tandem Critical Raw Material-Free Water Photoelectrolysis Cell Using a Hydrophobic Gas-Diffusion Backing Layer
Trocino S, Lo Vecchio C, Campagna Zignani S, Carbone A, Saccà A, Baglio V, Gómez R, Aricò AS. Dry Hydrogen Production in a Tandem Critical Raw Material-Free Water Photoelectrolysis Cell Using a Hydrophobic Gas-Diffusion Backing Layer. Catalysts. 2020; 10(11):1319. https://doi.org/10.3390/catal10111319
URI: http://hdl.handle.net/10045/111083
DOI: 10.3390/catal10111319
ISSN: 2073-4344
Abstract: 
A photoelectrochemical tandem cell (PEC) based on a cathodic hydrophobic gas-diffusion backing layer was developed to produce dry hydrogen from solar driven water splitting. The cell consisted of low cost and non-critical raw materials (CRMs). A relatively high-energy gap (2.1 eV) hematite-based photoanode and a low energy gap (1.2 eV) cupric oxide photocathode were deposited on a fluorine-doped tin oxide glass (FTO) and a hydrophobic carbonaceous substrate, respectively. The cell was illuminated from the anode. The electrolyte separator consisted of a transparent hydrophilic anionic solid polymer membrane allowing higher wavelengths not absorbed by the photoanode to be transmitted to the photocathode. To enhance the oxygen evolution rate, a NiFeOX surface promoter was deposited on the anodic semiconductor surface. To investigate the role of the cathodic backing layer, waterproofing and electrical conductivity properties were studied. Two different porous carbonaceous gas diffusion layers were tested (Spectracarb® and Sigracet®). These were also subjected to additional hydrophobisation procedures. The Sigracet 35BC® showed appropriate ex-situ properties for various wettability grades and it was selected as a cathodic substrate for the PEC. The enthalpic and throughput efficiency characteristics were determined, and the results compared to a conventional FTO glass-based cathode substrate. A throughput efficiency of 2% was achieved for the cell based on the hydrophobic backing layer, under a voltage bias of about 0.6 V, compared to 1% for the conventional cell. For the best configuration, an endurance test was carried out under operative conditions. The cells were electrochemically characterised by linear polarisation tests and impedance spectroscopy measurements. X-Ray Diffraction (XRD) patterns and Scanning Electron Microscopy (SEM) micrographs were analysed to assess the structure and morphology of the investigated materials.
Keywords:Water splitting, Photoelectrolysis cell, Photoelectrochemical cell, Carbonaceous gas diffusion layer, Green hydrogen, Dry hydrogen, Semiconductor, Solar fuel, Non-critical raw materials, Solar-to-fuel efficiency
MDPI
info:eu-repo/semantics/article