Solar kerosene from H2O and CO2

“…The maximum CO production rate reached ~9.4 mL/g/min for oxidation in 100% CO 2 (cycle #28 in Table 1). This means that a 8 fold-increase of the fuel production rate was achieved with the studied microstructured ceria foams (microstructural characterization provided in the next section), when compared to previously reported values [18,23,24,32]. The fuel production rate can even be enhanced further (up to 9.9 mL/g/min for cycle #32) by increasing the total gas flow-rate (inducing products dilution).…”

“…Furthermore, the CO production rate was remarkably high, in the range of 4 to 7 mL/g/min, representing the highest rates obtained to date with ceria and thus a strong improvement in the performance of solar fuel reactors based on reticulated porous ceria. In comparison, Furler et al [23,24,32] obtained a maximal fuel production rate of 1.2 mL/g/min with more stringent operational conditions (1450°C and 10 hPa) in an electrically-heated high-flux simulator using ceria foams with dual-scale porosity. In the present study, the microstructured ceria foams were subjected to real concentrated high-flux solar radiation in a scalable solar reactor and were found to sustain fuel production cycles without any reactivity loss.…”

“…Using a gas-phase heat recovery system, the solar-to-fuel efficiency reached 1.64 % without taking into account the inert gas energy costs [20]. An electrically-heated monolithic reactor irradiated by artificial light, with porous ceria as reactive material was developed elsewhere [21][22][23]. Stable and rapid fuel production was demonstrated over 500 cycles with peak and average solar-to-fuel efficiencies of 3.53 % and 1.73 %, respectively [22].…”

Remarkable performance of microstructured ceria foams for thermochemical splitting of H2O and CO2 in a novel high–temperature solar reactor

“…The maximum CO production rate reached ~9.4 mL/g/min for oxidation in 100% CO 2 (cycle #28 in Table 1). This means that a 8 fold-increase of the fuel production rate was achieved with the studied microstructured ceria foams (microstructural characterization provided in the next section), when compared to previously reported values [18,23,24,32]. The fuel production rate can even be enhanced further (up to 9.9 mL/g/min for cycle #32) by increasing the total gas flow-rate (inducing products dilution).…”

“…Furthermore, the CO production rate was remarkably high, in the range of 4 to 7 mL/g/min, representing the highest rates obtained to date with ceria and thus a strong improvement in the performance of solar fuel reactors based on reticulated porous ceria. In comparison, Furler et al [23,24,32] obtained a maximal fuel production rate of 1.2 mL/g/min with more stringent operational conditions (1450°C and 10 hPa) in an electrically-heated high-flux simulator using ceria foams with dual-scale porosity. In the present study, the microstructured ceria foams were subjected to real concentrated high-flux solar radiation in a scalable solar reactor and were found to sustain fuel production cycles without any reactivity loss.…”

“…Using a gas-phase heat recovery system, the solar-to-fuel efficiency reached 1.64 % without taking into account the inert gas energy costs [20]. An electrically-heated monolithic reactor irradiated by artificial light, with porous ceria as reactive material was developed elsewhere [21][22][23]. Stable and rapid fuel production was demonstrated over 500 cycles with peak and average solar-to-fuel efficiencies of 3.53 % and 1.73 %, respectively [22].…”

Remarkable performance of microstructured ceria foams for thermochemical splitting of H2O and CO2 in a novel high–temperature solar reactor

“…e Average per carbon atom. f CO 2 converted to CO, in turn converted to hydrocarbons via Fischer-Tropsch synthesis 85 .…”

The renaissance of the Sabatier reaction and its applications on Earth and in space

“…In addition, thermal applications have been recently proposed in the so-called Concentrating Solar Thermal, CST. Two of such high-temperatures examples can be found in the green production of hydrogen [2] and sustainable aviation fuels (SAF) [3], which, driving endothermic reactions at high temperatures through solar heat, are able to produce fuels from water and CO2 and thus to effectively close the fossil fuel carbon cycle [4], but which require temperatures from above 700 °C up to ~1550 °C. These solar-driven chemical processes show an outstanding potential.…”

Novel ceramic fibre - Zirconium diboride composites for solar receivers in concentrating solar power systems