Reversible Solid Oxide Fuel Cell Technology for Green Fuel and Power Production

Abstract: A reversible solid oxide fuel cell (RSOFC) is a device that can operate efficiently in both fuel cell and electrolysis operating modes. Thus, in the fuel cell mode, an RSOFC functions as an SOFC, generating electricity by electrochemical combination of a fuel (hydrogen, hydrocarbons, alcohols, etc.) with air (oxygen in the air). In the electrolysis mode, an RSOFC functions as an electrolyzer (in this case, referred to as a solid oxide electrolysis cell or SOEC), producing hydrogen (from water) or chemicals s… Show more

“…We propose that a higher surface concentration of reaction sites on the ceria nanoparticles in CO/CO 2 respectively (speculated to be so at ambient pressure).…”

“…[1][2][3][4] Furthermore, SOCs can operate with carbonaceous feedstocks (hydrocarbons, CO, CO 2 , etc.) [5][6][7][8] A good physical and chemical understanding of the electrochemical reactions (ERs) that occur in the fuel-electrode, CO 2 , is crucial for addressing performance and lifetime limiting factors as well as for designing new improved electrodes. The reactions take place either at the 3-phase boundary (3PB) between the gas, O 2À conductor and e À conductor, or at the 2-phase boundary (2PB) between the gas and the surface of a mixed ionic and electronic conducting (MIEC) solid, depending on the electrode materials.…”

Kinetics of CO/CO₂ and H₂/H₂O reactions at Ni-based and ceria-based solid-oxide-cell electrodes

“…We propose that a higher surface concentration of reaction sites on the ceria nanoparticles in CO/CO 2 respectively (speculated to be so at ambient pressure).…”

“…[1][2][3][4] Furthermore, SOCs can operate with carbonaceous feedstocks (hydrocarbons, CO, CO 2 , etc.) [5][6][7][8] A good physical and chemical understanding of the electrochemical reactions (ERs) that occur in the fuel-electrode, CO 2 , is crucial for addressing performance and lifetime limiting factors as well as for designing new improved electrodes. The reactions take place either at the 3-phase boundary (3PB) between the gas, O 2À conductor and e À conductor, or at the 2-phase boundary (2PB) between the gas and the surface of a mixed ionic and electronic conducting (MIEC) solid, depending on the electrode materials.…”

Kinetics of CO/CO₂ and H₂/H₂O reactions at Ni-based and ceria-based solid-oxide-cell electrodes

“…In general, SOECs can operate reversibly in both electrolysis and fuel cell modes. 23) To reveal the electrode behavior, the iV curve in fuel cell mode was also measured. Here, the feed rate of the supplied gaseous mixture to the fuel electrode was a sufficiently high value for electrolysis to avoid the depletion of H 2 O at the surface of the fuel electrode.…”

“…This might be a consequence of concentration polarization due to a low water partial pressure, p H2O , compared with hydrogen partial pressure, p H2 , in the supplied fuel. Also, because the oxygen electrode performance at high i in the electrolysis mode is often irreversible to the fuel cell mode, 23) the increase in V in the electrolysis mode might be attributed to the oxygen electrode reaction. Figure 3 shows the impedance spectra for the SOEC at different V in electrolysis mode.…”

“…For electrode polarization, the increase in R 1 and R 2 was considered due to the decreasing performance of the oxygen electrode with increasing i in electrolysis mode. 23) Also, the increasing R 3 indicates that the concentration polarization resistance of the fuel electrode was severely affected i even though H 2 O for electrolysis was supplied in excess. This suggests that reducing the concentration polarization resistance is essential to achieve high U steam and high i operation.…”

High steam utilization operation with high current density in solid oxide electrolysis cells

Materials selection and R&D for commercial fuel cells