Efficient heat transfer of concentrated solar energy and rapid chemical kinetics are desired
characteristics of solar thermochemical redox cycles for splitting CO2. We have fabricated …

Solar thermochemical H 2 O and CO 2 splitting cycles represent an efficient route for
converting high temperature concentrated solar heat into valuable chemical energy carriers …

Thermochemical splitting of H 2 O and CO 2 applying redox materials constitutes a
sustainable option for synthetic fuel production and CO 2 valorization. It consists of two-step …

A solar cavity-receiver containing a reticulated porous ceramic (RPC) foam made of pure
CeO2 has been experimentally investigated for CO2 splitting via thermochemical redox …

This review explores the advances in the synthesis of ceria materials with specific
morphologies or porous macro-and microstructures for the solar-driven production of carbon …

This work addresses the solar-driven thermochemical production of CO and O 2 from two-
step CO 2-splitting cycles, using both ceria granules prepared from cork templates (CG) and …

Developing solar technologies for converting CO2 into fuels has become a great energy
challenge, as it closes the anthropogenic carbon cycle and leads to the production of …

Solar thermochemical cycles offer a viable option for the production of green synthetic fuels
from CO 2 and H 2 O. Two-step cycles using redox materials consist of a high-temperature …

A solar reactor consisting of a cavity-receiver containing a reticulated porous ceramic (RPC)
foam made of CeO 2 is considered for effecting the splitting of H 2 O and CO 2 via a …

Splitting CO 2 with a thermochemical redox cycle utilizes the entire solar spectrum and
provides a favorable path to the synthesis of solar fuels at high rates and efficiencies …