The sulfur-iodine (S–I or I–S) thermochemical cycle is viewed as a leading method for
hydrogen production due to its environmental sustainability, cost-efficiency, and high …

The decomposition of sulfuric acid to sulfur dioxide is an important reaction section in both
the thermochemical Iodine–Sulfur (IS) cycle and the Hybrid (Hybs) cycle for hydrogen …

Research and development on the thermochemical water-splitting cycle using iodine and
sulfur, a potential large-scale hydrogen production method, is reviewed. Feasibility of the …

The first technical developments on thermochemical cycles for hydrogen production are
based on the use of sulphur as a redox material. After the oil crises of the 1970s, high …

Through our previous studies it was established that non-precious Fe 2 O 3 based catalyst
has the potential to replace Pt based catalyst for high temperature sulfuric acid …

The catalytic decomposition of sulfuric acid is the most endothermic step of the sulfur based
water splitting thermochemical cycles, which are promising technologies for large scale …

To address the issues of catalytic activity and stability of the promising Fe 2 O 3/SiO 2
catalyst for sulfuric acid decomposition, Fe 2 O 3 was immobilized on SiO 2 support by …

Supported iron oxides have been established as an important class of catalyst for high
temperature sulfuric acid decomposition. With an objective to elucidate the role of support in …

Activity and stability of FeTiO3, MnTiO3, NiFe2O4, CuFe2O4, NiCr2O4, 2CuO· Cr2O3, CuO
and Fe2O3 for the atmospheric decomposition of concentrated sulfuric acid in sulfur-based …

Detailed investigations of CuCl2 hydrolysis step of Cu–Cl thermochemical cycle were
carried out on various aspects:(a) characterization and thermal properties of …