A method for making a metal-hydride slurry includes adding metal to a liquid carrier to create a metal slurry and hydriding the metal in the metal slurry to create a metal-hydride slurry. In some embodiments, a metal hydride is added to the liquid carrier of the metal slurry prior to hydriding the metal. The metal can be magnesium and the metal hydride can be magnesium hydride.

A system and method for converting a common hydrogen-based input fluid into an output fluid comprising an overabundance of hydrogen H.sub.1 atoms is disclosed. This conversion occurs in the absence of elevated temperatures or pressures, so that the resulting output fluid is suitable for shipping or storage at Standard Temperature and Pressure (STP). A vaporizer system and method for transforming the output fluid into H2 gas is also disclosed.

A system and method for converting a common hydrogen-based input fluid into an output fluid comprising an overabundance of hydrogen H.sub.1 atoms is disclosed. This conversion occurs in the absence of elevated temperatures or pressures, so that the resulting output fluid is suitable for shipping or storage at Standard Temperature and Pressure (STP). A vaporizer system and method for transforming the output fluid into H2 gas is also disclosed.

Methods are disclosed for generating electrical power from a compound comprising carbon, oxygen, and hydrogen. Water is combined with the compound to produce a wet form of the compound. The wet form of the compound is transferred into a reaction processing chamber. The wet form of the compound is heated within the reaction chamber such that elements of the compound dissociate and react, with one reaction product comprising hydrogen gas. The hydrogen gas is processed to generate electrical power.

This invention introduces practical procedures for concentration, purification and utilization of rare antigravitational hydrogen atoms created during early universe or later violent astronomical events following pair-production symmetry. A tall cryogenic concentration container maintains liquid hydrogen at extremely low, uniform and stable temperature with minimal convection and thermal diffusion. Rare molecules with zero gravity containing one rare antigravitational hydrogen atoms drift up and accumulate to the top by buoyancy. The concentrated zero-gravity hydrogen molecules are then chemically and/or physically broken down into individual atoms and recombined resulting in hydrogen molecules carrying normal gravity, zero gravity, and repulsive antigravity, respectively. When liquified and maintained in the cryogenic concentration container, the antigravitational hydrogen molecules are repelled to the top to be separated and purified. Cryogenic containers holding purified antigravitational liquid hydrogen can provide sustained levitation and propulsion for vehicles, aircrafts, space elevators, satellites, and spacecrafts consuming no fuel or energy.

A power source and hydride reactor is provided comprising a reaction cell comprising a solid reaction mixture which undergoes one or more chemical reactions providing a net positive enthalpy of reaction. Power and chemical plants that can be operated continuously using electrolysis or thermal regeneration reactions involving these solid fuels are also provided herein. The solid fuel reaction mixture may comprise: (a) inorganic halide, inorganic oxide selected from Y.sub.2O.sub.3, SnO.sub.2, As.sub.2O.sub.3, Bi.sub.2O.sub.3, FeO, TeO.sub.2, P.sub.2O.sub.5 , and SeO.sub.2, inorganic nitrate selected from NaNO.sub.3 and LiNO.sub.3, metal carbide selected from TiC, and WC, inorganic nitride selected from Mg.sub.3N.sub.2, AlN, Zn.sub.3N.sub.2, and Ca.sub.3N.sub.2, inorganic sulfide selected from Li.sub.2S, ZnS, CoS, Sb.sub.2S.sub.5, MnS, Cu.sub.2S, Y.sub.2S.sub.3, CuS, FeS, Sb.sub.2S.sub.5, and CS.sub.2, inorganic boride selected from CrB.sub.2 and TiB.sub.2, or combinations thereof; (b) metal hydride or metal hydroxide; and (c) one or more metals.