Abstract
A thermodynamic analysis was conducted on a solar thermochemical plant for syngas generation via H2O/CO2-splitting redox cycles in order to determine the performance of six candidate redox materials under an array of operation conditions. The values obtained for the solar-to-fuel energy conversion efficiency are higher in relative order Zr-doped CeO2 > undoped CeO2 > La0.6Ca0.4MnO3 > La0.6Ca0.4Mn0.6Al0.4O3 > La0.6Sr0.4MnO3 > La0.6Sr0.4Mn0.6Al0.4O3. This ordering is attributed to their relative reducibility and re-oxidizability, where the doped and undoped ceria, that favor oxidation, outperform perovskites, that favor reduction and therefore require high flowrates of excess H2O and CO2 during re-oxidation. Solids-solid heat recuperation during the temperature swing between the redox steps is crucial, particularly for ceria because of its low specific oxygen exchange capacity per mole and cycle. Conversely, the efficiencies of the perovskites are more dependent on gas-gas heat recuperation due to the massive excess of H2O/CO2. Redox material thermodynamics and plant/reactor performance are closely coupled, and must be considered together to maximize efficiency. Overall, we find that Zr-CeO2 is the most promising redox material, while perovskites which seem promising due to high H2/CO production capacities under large H2O/CO2 flow rates, perform poorly from an efficiency perspective due to the high heating duties, especially for steam.
Highlights
Concentrated solar thermochemical gas splitting (STGS) of H2O and/or CO2 is a promising approach for renewable H2 and/ or CO production because of its high theoretical solar-to-fuel energy conversion efficiency as a result of the utilization of the entire solar spectrum [1e5]
We showed that the materials have relative performances of ZrCeO2 > CeO2 > La0.6Ca0.4MnO3 > La0.6Ca0.4 Mn0.6Al0.4O3 > La0.6Sr0.4MnO3 > La0.6Sr0.4Mn0.6Al0.4O3, and that this ordering is relatively independent of system parameters or operating points, with the caveat that CeO2 outperforms Zr-CeO2 for CO2 splitting in systems with high solids heating recuperation
The performance of ceria based materials (Zr-CeO2 and CeO2) are most influenced by the solid-solid heat recuperation, while the LCM and LSM are correlated to reduction temperature and O2 partial pressure, and LCMA and LSMA are correlated to gasgas heat recuperation
Summary
Concentrated solar thermochemical gas splitting (STGS) of H2O and/or CO2 is a promising approach for renewable H2 and/ or CO production because of its high theoretical solar-to-fuel energy conversion efficiency (hsolar-to-fuel) as a result of the utilization of the entire solar spectrum [1e5]. In two-step STGS, concentrated sunlight drives the reduction of a metal oxide at Tred, releasing O2, as shown in Eq (1). DHred ε enthalpy of reduction (kJ/mol) emissivity εgg gas-gas heat exchanger effectiveness εss effectiveness of the solids heat exchanger hO2-rem O2 removal efficiency hoptic efficiency of optical collection hsep efficiency of gas separation hsolar-to-fuel solar to fuel efficiency. C solar concentration ratio cpsolid heat capacity of the solid (kJ/mol). HHVH2 Isolar Kdissoc higher heating value of hydrogen (kJ/mol) direct normal solar irradiance (kw/m2).
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
