REFORMSOFC – X-POWERED REFORMING CATALYST-SUPPORTED SOLID OXIDE FUEL CELL
The REFORM-SOFC project proposes a new concept of a highly porous catalytic layer of metal-ceramic composite for Solid Oxide Fuel Cell (SOFC) performing two functions: (i) promoting internal reforming of synthetic methanol or biogas on metal nanoparticles; (ii) acting as a structural support of the electrochemical cell. Moving from the state-of-the-art Anode-Supported (AS-SOFC) design to the Reforming Catalyst-Supported (RCS-SOFC) design will allow to reduce amount of ceramic powder used for production, reduce the thickness of the anode and avoid its coking while maintaining the mechanical strength. Overall, the RCS-SOFC design: (i) enables the flexible customization of the microstructure of the catalytic/structural layer towards efficient reforming of fuel with the formation of hydrogen and (ii) prevents the blocking of conventional Ni/3YSZ anodes layer by carbon deposits.
Fecha de inicio
01/11/2025
Fecha de finalización
31/10/2028
Entidad financiadora
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Junta de Extremadura + European Comission
Convocatoria
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Pilar III. Excelencia Científica. MSCA-COFUND (Talent4Iberia)
Investigador(es) principal(es)
Difusión de ayuda
The REFORM-SOFC project proposes a new concept of a highly porous catalytic layer of metal-ceramic composite for Solid Oxide Fuel Cell (SOFC) performing two functions: (i) promoting internal reforming of synthetic methanol or biogas on metal nanoparticles; (ii) acting as a structural support of the electrochemical cell. Moving from the state-of-the-art Anode-Supported (AS-SOFC) design to the Reforming Catalyst-Supported (RCS-SOFC) design will allow to reduce amount of ceramic powder used for production, reduce the thickness of the anode and avoid its coking while maintaining the mechanical strength. Overall, the RCS-SOFC design: (i) enables the flexible customization of the microstructure of the catalytic/structural layer towards efficient reforming of fuel with the formation of hydrogen and (ii) prevents the blocking of conventional Ni/3YSZ anodes layer by carbon deposits.
