High-temperature solar thermal energy systems make use of concentrated solar radiation to
generate electricity, produce chemical fuels, and drive energy-intensive processing of …

Carbon dioxide (CO 2) is the most important greenhouse gas (GHG), accounting for 76% of
all GHG emissions. The atmospheric CO 2 concentration has increased from 280 ppm in the …

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 …

Chemical looping can provide attractive alternative process routes in which solid oxygen
carriers function as lattice oxygen transfer agents, for example for the partial oxidation of …

Solar-driven thermochemical conversion of H 2 O and CO 2 into sustainable fuels, based on
redox cycle, provides a promising path for alternative energy, as it employs the solar energy …

The receiver/reactor engineering and radiative power distribution technology are still
challenging the development and rapid upscaling of solar thermal conversion and storage …

The solar thermochemical two-step splitting of H2O and CO2 based on metal oxide
compounds is a promising path for clean and efficient generation of hydrogen and …

Green hydrogen can be produced by thermochemical redox cycles utilizing concentrated
solar energy. A high solar-to-fuel efficiency, as well as a robust system design, is crucial. As …

Porous ceramic foams are utilized in various fields and applications due to their
advantageous properties such as high porosity, high specific surface area, and controlled …

In the evolving landscape of sustainable energy solutions, the approach of two-step solar
thermochemical cycles assumes a position of paramount importance. Metal oxide oxygen …