The electronic structure of nanowires, nanotubes and thin films deposited on a substrate is varied by doping with electrons or holes. The electronic structure can then be tuned by varying the support material or by applying a gate voltage. The electronic structure can be controlled to absorb a gas, store a gas, or release a gas, such as hydrogen, oxygen, ammonia, carbon dioxide, and the like.

A pyrotechnic process for providing very high purity hydrogen, includes the combustion of at least one solid pyrotechnic charge capable of generating hydrogen-containing gas for the production of a pressurized hot hydrogen-containing gas that contains at least 70% by volume of hydrogen; and the purification of at least one portion of the pressurized hydrogen-containing gas, by passing through a metallic hydrogen separation membrane maintained at a temperature above 250 C., in order to obtain, at the outlet of the membrane, a hydrogen-containing gas that contains at least 99.99% by volume of hydrogen.

The electronic structure of nanowires, nanotubes and thin films deposited on a substrate is varied by doping with electrons or holes. The electronic structure can then be tuned by varying the support material or by applying a gate voltage. The electronic structure can be controlled to absorb a gas, store a gas, or release a gas, such as hydrogen, oxygen, ammonia, carbon dioxide, and the like.

A catalyzed metal hydride alloy is disclosed, which includes lithium amide and magnesium hydride and rubidium hydride is the catalyst. A method of making the metal hydride alloy includes combining rubidium hydride with lithium amide and magnesium hydride in a vessel to form a mixture and mechanically milling the mixture. A method of manufacturing rubidium hydride is also disclosed which includes milling rubidium metal in a vessel pressurized with hydrogen gas at an initial minimum rotation rate and increasing the rotation rate to a maximum rotation rate, alternating between periods of milling and rest, re-pressurizing the vessel with hydrogen during the rest periods, and incubating the contents of the vessel.

The present invention concerns a hydrogen store comprising a hydrogenable material, and a method for producing a hydrogen store.

A hydrogen compression system includes an inner container made of a non-magnetic element and having a hydrogen inlet/outlet portion through which hydrogen flows in or out of the inner container, a metal hydride material accommodated in the inner container, an outer container configured to surround the inner container and having an inlet/outlet port through which hydrogen flows in or out of the outer container, and an induction heating unit disposed between the inner container and the outer container and configured to heat the metal hydride material by induction heating, thereby obtaining an advantageous effect of simplifying a structure and process for heating the metal hydride material and quickly heating the metal hydride material to an accurate temperature.

A hydrogen generating element of an electrochemical apparatus may include a compacted homogenous body of an alloy-like material which contains at least 60 wt.-%, preferably more than 75 wt.-%, of Mg or a Mg alloy, 5 to 20 wt.-% Fe.sub.2O.sub.3, and 5 to 20 wt.-% of an electrolyte precursor material.

A heat generating method includes: heating, with a heater, a heat generating element and causing a first heat generating reaction in which the heat generating element generates heat with a first heat generation amount and triggering a second heat generating reaction in which the heat generating element generates heat with a second heat generation amount larger than the first heat generation amount, by imparting a perturbation to an input power to be applied to the heater in a state where the first heat generating reaction is occurring. The heat generating element includes a base made of a hydrogen storage metal, a hydrogen storage alloy, or a proton conductor, and a multilayer film provided on a surface of the base, with a stacked configuration of a first layer and a second layer made of different materials and both having a thickness of less than 1,000 nm.

The hydrogen storage element for a hydrogen store comprises a pressed article having a hydrogen-storing first material and having a thermally conductive second material, wherein the second material is in thermal contact with the hydrogen-storing first material and has, in some regions, a different three-dimensional distribution within the pressed article.

This disclosure relates to novel metal hydrides, processes for their preparation, and their use in hydrogen storage applications.