Water splitting

[3][4] Since the active site of the OEC contains manganese, much research has aimed at synthetic Mn compounds as catalysts for water oxidation.[5] In biological hydrogen production, the electrons produced by the photosystem are shunted not to a chemical synthesis apparatus but to hydrogenases, resulting in formation of H2.Again, water is broken down into hydrogen and oxygen by electrolysis, but the electrical energy is obtained by a photoelectrochemical cell (PEC) process.In the Mponeng gold mine, South Africa, researchers found in a naturally high radiation zone a community dominated by Desulforudis audaxviator, a new phylotype of Desulfotomaculum, feeding on primarily radiolytically produced H2.[15] The high temperature requirements and material constraints have limited the applications of the thermal decomposition approach.Other research includes thermolysis on defective carbon substrates, thus making hydrogen production possible at temperatures just under 1,000 °C (1,270 K; 1,830 °F).As of 2005, there was sufficient hydrogen demand in the United States that all daily peak generation could be handled by such plants.Hydrosol-2 is a 100-kilowatt pilot plant at the Plataforma Solar de Almería in Spain which uses sunlight to obtain the required 800 to 1,200 °C (1,070 to 1,470 K; 1,470 to 2,190 °F) to split water.A "Solar Water Cracker" with a concentrator of about 100 m2 can produce almost one kilogram of hydrogen per sunshine hour.
Diagram of the chemical equation of the electrolysis of water , a form of water splitting.
Atmospheric electricity utilization for the chemical reaction in which water is separated into oxygen and hydrogen. (Image via: Vion, US patent 28793. June 1860.)
Electrolyser front with electrical panel in foreground
Water electrolysis ship Hydrogen Challenger
An algae bioreactor for hydrogen production.
chemical equationelectrolysis of waterchemical reactionoxygenhydrogenhydrogen economyphotosynthesishydrogen fuel cellAtmospheric electricityHydrogen Challengerhigh-temperature electrolysisefficiencysteam electrolysisphotosystem IIphotosystem Iplastoquinonecytochromesplastocyaninoxygen-evolving complexactive sitemanganesealgae bioreactorbiological hydrogen productionhydrogenasesbiohydrogenbioreactorPhotoelectrolysis of waterphotovoltaicphotoelectrochemical cellartificial photosynthesisPhotocatalytic water splittingMponenggold mineSouth AfricaDesulforudis audaxviatorphylotypeDesulfotomaculumradiolyticallyThermochemical cyclethermolysiscarbonNext Generation Nuclear Plantelectricitygrid energy storageUnited Statescopper–chlorine cyclecogenerationwaste heatsupercritical water reactorConcentrated solar powerPlataforma Solar de Almeríaheliostatsulfur–iodine cyclethermochemicalproduce hydrogenchemical reactionsthermochemical cyclesCerium(IV) oxide–cerium(III) oxide cycleHybrid sulfur cycleZinc–zinc oxide cycleIron oxide cycleBibcodeU.S. Department of Energy