Add to ORKGExperimental studies have validated three classes of thermochemical cycles (Bismuth sulfate-sulfuric acid, magnesium sulfate-magnesium iodide, and oxide-based) based on high temperature solids decomposition as an endothermic step. Such cycles offer the possibility of high efficiency when coupled with high temperature isothermal heat sources. Methods for handling solids in high temperature decomposition reactions have been tested. The results suggest that efficient and practical cycles can be based on such reactions
Decomposition of sulphuric acid is a key step of sulphur based thermochemical cycles for hydrogen pr...
Thermochemical water splitting cycles, where the H2O molecule is converted into hydrogen and oxygen ...
Thermochemical water splitting cycles, where the H2O molecule is converted into hydrogen and oxygen ...
Some of the criteria required for high temperature thermochemical hydrogen cycles to couple efficien...
REVERSIBLE THERMOCHEMICAL REACTIONS ARE ONE OF THE POSSIBILITIES TO STORE HIGH TEMPERATU...
The use of solar energy to produce hydrogen from water is an attractive concept that merits a contin...
The thermochemical cycles which have been most extensively developed all involve the thermal decompo...
The first technical developments on thermochemical cycles for hydrogen production are based on the u...
The first technical developments on thermochemical cycles for hydrogen production are based on the u...
There is a significant opportunity to store solar energy using hydrogen if a suitable thermochemical...
The LASL bismuth sulfate cycle is one of a generic class of solid sulfate cycles in which a metal su...
The LASL Hydrogen Program is continuing its investigation of practical schemes to decompose water th...
A promising way to use heat from carbon-free sources like concentrated solar is to drive chemical re...
The sulfur-iodine (S-I) thermochemical water splitting cycle is one of the most studied cycles for h...
A modification of the sulfur dioxide-iodine cycle which uses magnesium oxide, magnesium sulfite and ...
Decomposition of sulphuric acid is a key step of sulphur based thermochemical cycles for hydrogen pr...
Thermochemical water splitting cycles, where the H2O molecule is converted into hydrogen and oxygen ...
Thermochemical water splitting cycles, where the H2O molecule is converted into hydrogen and oxygen ...
Some of the criteria required for high temperature thermochemical hydrogen cycles to couple efficien...
REVERSIBLE THERMOCHEMICAL REACTIONS ARE ONE OF THE POSSIBILITIES TO STORE HIGH TEMPERATU...
The use of solar energy to produce hydrogen from water is an attractive concept that merits a contin...
The thermochemical cycles which have been most extensively developed all involve the thermal decompo...
The first technical developments on thermochemical cycles for hydrogen production are based on the u...
The first technical developments on thermochemical cycles for hydrogen production are based on the u...
There is a significant opportunity to store solar energy using hydrogen if a suitable thermochemical...
The LASL bismuth sulfate cycle is one of a generic class of solid sulfate cycles in which a metal su...
The LASL Hydrogen Program is continuing its investigation of practical schemes to decompose water th...
A promising way to use heat from carbon-free sources like concentrated solar is to drive chemical re...
The sulfur-iodine (S-I) thermochemical water splitting cycle is one of the most studied cycles for h...
A modification of the sulfur dioxide-iodine cycle which uses magnesium oxide, magnesium sulfite and ...
Decomposition of sulphuric acid is a key step of sulphur based thermochemical cycles for hydrogen pr...
Thermochemical water splitting cycles, where the H2O molecule is converted into hydrogen and oxygen ...
Thermochemical water splitting cycles, where the H2O molecule is converted into hydrogen and oxygen ...