A hybrid method for hydrogen storage and generation from water

“…Compared to the physical approaches such as liquefaction and compression, hydrogen storage in the solid state has merits in terms of high volumetric and gravimetric hydrogen contents and, most importantly, safety [1]. Research in many laboratories around the world has focused on the solid-state hydrogen storage materials that are based on three primary approaches: (1) using inorganic solid hydride materials that have reversible dehydrogenation and rehydrogenation characteristics [2][3][4][5][6][7][8][9], (2) using the hydrolysis of alkali-and alkaline-earth metal hydrides and complex hydrides (such as MgH 2 , LiH, LiAlH 4 and LiBH 4 ) [10,11] and (3) using carbon or other adsorbent materials to store hydrogen based on surface adsorption and desorption [12][13][14]. The critical characteristic properties of a solid hydrogen storage material include storage capacity, dehydrogenation temperature, plateau pressure and the reversibility of dehydrogenation and rehydrogenation.…”

Hydrogen storage properties of the Mg–Ti–H system prepared by high-energy–high-pressure reactive milling

“…Compared to the physical approaches such as liquefaction and compression, hydrogen storage in the solid state has merits in terms of high volumetric and gravimetric hydrogen contents and, most importantly, safety [1]. Research in many laboratories around the world has focused on the solid-state hydrogen storage materials that are based on three primary approaches: (1) using inorganic solid hydride materials that have reversible dehydrogenation and rehydrogenation characteristics [2][3][4][5][6][7][8][9], (2) using the hydrolysis of alkali-and alkaline-earth metal hydrides and complex hydrides (such as MgH 2 , LiH, LiAlH 4 and LiBH 4 ) [10,11] and (3) using carbon or other adsorbent materials to store hydrogen based on surface adsorption and desorption [12][13][14]. The critical characteristic properties of a solid hydrogen storage material include storage capacity, dehydrogenation temperature, plateau pressure and the reversibility of dehydrogenation and rehydrogenation.…”

Hydrogen storage properties of the Mg–Ti–H system prepared by high-energy–high-pressure reactive milling

“…1 Additionally, Li is a well-established energy carrier and an element of processes that generate hydrogen via the Li–water interaction, Li hydrides, and borohydrides. 4–6 Also, Li has been proposed as fuel for submarines and rockets, 1 and it has been incorporated into underwater propulsion systems as a chemical fuel. 1,7,8…”

“…1 Additionally, Li is a well-established energy carrier and an element of processes that generate hydrogen via the Li-water interaction, Li hydrides, and borohydrides. [4][5][6] Also, Li has been proposed as fuel for submarines and rockets, 1 and it has been incorporated into underwater propulsion systems as a chemical fuel. 1,7,8 Generally, metals have traditionally been known to be good energy storage resources in addition to being effective additives in slurry fuels, energetic materials, and propellants by virtue of their high specic energy.…”

Atomic-level investigation on the oxidation efficiency and corrosion resistance of lithium enhanced by the addition of two dimensional materials

“…Hydrogen is mainly used for transportation and stationary applications (Lu et al, 2007;Toonssen et al, 2008). On site hydrogen production from natural gas by steam reforming of methane is one of the most promising processes to produce hydrogen at hydrogen refueling stations.…”

Development of compact and efficient hydrogen production module with membrane on catalyst