Periodic Reporting for period 3 - SElySOs (Development of new electrode materials and understanding of degradation mechanisms on Solid Oxide High Temperature Electrolysis Cells.)
Okres sprawozdawczy: 2018-11-02 do 2020-05-01
In regards to the model/s development and validation a multi-dimensional, stationary, isothermal model of solid oxide steam-CO2 co-electrolysis (SOcoE) cell was successfully developed in agreement with the project aims. The model was thoroughly validated, and its physical validity demonstrated, in the broad range of temperature and gaseous reaction mixture composition. One key result is that heterogeneously catalyzed chemical reactions play a key role in the final composition of the produced gas mixture. Finally, a 0-D model analysis of the degradation of the symmetrical cell with LNO-GDC oxygen electrode was also performed.
In the case of the Ni-based fuel cathodes, the cells comprising the Au-Mo modified electrodes exhibited quite better electrochemical performance, compared to the SoA Ni/GDC. In this respect, the nominated Ni-based fuel electrode for the H2O electrolysis was the 3Au-3Mo-Ni/GDC. Regarding the Ni-metal free electrodes, the Fe substituted chromite (LSCrF) electrode was the proposed fuel electrode for H2O & H2O/CO2 co-electrolysis. Finally, in the case of the new developed air electrodes for SOECs two are the proposed candidates for oxygen electrodes and these are PNCO-20 and LPNO. The nominated samples/electrodes were used for: (•) the preparation and testing (for H2O electrolysis) of “combinatorial” button cells, comprising as well the proposed O2 electrodes, (•) the preparation of larger cells for long-term stability tests and (•) the stack/s preparation and testing. Moreover, “Three-layer” and “five-layer” free standing solid oxide cells were manufactured exclusively by Thermal Spray.
Long-term stability investigation of the Ni-metal-free fuel electrodes aimed at the target of 1000 hours of operation. The performance of two cells, one with LSCrF/GDC//3YSZ//GDC/LSCoF/LNF and of a second with LSCrF/GDC//3YSZ/LSM-YSZ/LSM was examined and compared under 23.5% H2O/He electrolysis in the absence of H2 under steady-state operation with constant current density of 0.25 A cm-2 at 900˚C.
The enhancing effect of the 3Au-3Mo-Ni/GDC (modified Ni-based) fuel electrode was further verified with the use of the new O2 electrodes in the form of the so called “combinatorial” cells.
The electrochemical performance and long term stability of 8YSZ electrolyte supported 5x5 cm² single cells, comprising the best performing developed electrodes, was also investigated. During the long term stability tests of 1700, 1150 and 850 hours, respectively, for 3 different large-sized (active area of 20 cm2) single cells, at -0.3 A/cm2 and 900C, the lower degradation rate was observed for the cell comprising the modified 3Mo-3Au-Ni/GDC/8YSZ/GDC/LSCF single cell.
In regards to the stack manufacture and long-term operation, there are comparative data between one stack built using large (active area 42 cm2) TRL4 ESCs with 3Au-3Mo-Ni/GDC electrode and of another stack with similar size Ni/GDC electrode, which were operated at 835C, 0.5 A/cm2. The degradation rate for the stack with modified cells was 300 mV/kh, whereas for the Ni/GDC stack it was 700 mV/kh. Conclusively, this kind of element-doping may be an important method to extend the life-time of SOECs.
Management and dissemination activities were realized through various web tools, newsletters, presentations to the wide public, as well as 8 Open Access publications and 89 participations in conferences.