CO2 and H2O conversion to solar fuels via two-step solar thermochemical looping using iron oxide redox pair

This study addresses the solar thermal dissociation of CO2 and H2O by two-step thermochemical looping using Fe3O4/FeO redox system. The reactions produce clean H-2 and/or CO and the only process inputs are abundant and low-cost H2O and CO2 feedstock with no heating value combined with high-temperature solar heat to drive the endothermic reactions. The produced syngas can serve as the precursor to a renewable synthetic liquid fuel. Solar concentrated energy is thus used to reenergize H2O and captured CO2 for ultimately reversing combustion. The two-step process consists of (1) the solar thermal reduction of iron(II,III) oxide to FeO and O-2 in a high-temperature solar chemical reactor heated by concentrated solar energy; and (2) the H2O/CO2 splitting with the solar-produced FeO to generate H-2/CO, respectively; the resulting Fe3O4 being indefinitely recycled to the first step. The CO2 and H2O splitting reactions with the synthesized FeO-rich material were investigated in the range 600-800 degrees C with a thermobalance and with a packed bed of reactive particles enclosed in a tubular reactor, which showed that nearly complete FeO conversion could be reached. The powder reactivity was analyzed as a function of the reactant (CO2 and/or H2O), the temperature, and the material composition. A concept of the solar reactor technology was finally developed and experimentally tested in batch mode operation for the thermal reduction of Fe3O4. The rotary cavity-type reactor was operated under controlled atmosphere at about 1600 C with a liquid phase of iron oxide subjected to thermal reduction. (C) 2011 Elsevier BM. All rights reserved.