Abstract: The present application discloses an exemplary exothermic reaction system that is configured to generate excess heat. Also disclosed is a set of procedures for preparing and operating the exothermic reaction system. A Residual Gas Analyzer (RGA) or a similar device such as a quadruple mass spectrometer is employed to ensure that each step in the set of procedures is complete before moving to the next step. The detailed steps in how to assemble and clean the exothermic reaction system are described along with the RGA test results that are used as calibration baseline.

Abstract: Provided is a reactant, a heat-generating device and a heat-generating method, which can generate heat more stable than conventionally possible. When the reactant (26) that is formed from a hydrogen storage metal and has a plurality of metal nanoparticles (metal nano-protrusion) having the nano-size formed on the surface is structured to be installed in a reactor that becomes a deuterium gas atmosphere, and thereby hydrogen atoms are occluded in the metal nanoparticle of the reactant 26, heat can be generated more stable than conventionally possible.

Abstract: Nuclear transformation method and apparatus can produce thermal energy and hydrogen with a simple structure. A reaction cell, made of metal material like iron, from which oxygen is discharged is heated by a heater at a temperature above 500° C. Water is supplied into the reaction cell to be changed into steam which reacts on the inner wall of the reaction cell to produce hydrogen and thermal energy through a nuclear transformation. In the case that a reaction agent (NaOH, K2TiO3) which includes at least alkaline metal and oxygen is accommodated in the reaction cell, a nuclear reaction occurs without the supply of water.

Abstract: A method for producing conductor fine particles in which the advantages of conventional vapor phase method and liquid phase method are utilized while eliminating the drawbacks of both methods remarkably. Furthermore, definite guidelines and measure for improvement are given to the greatest problems common to the vapor phase method and liquid phase method, i.e., enhancement in quality of the unit fine particle and a fine particle production method controllably temporarily and regionally. The method for producing conductor fine particles comprises a step for applying a voltage to a pair of electrode consisting of a positive electrode and a negative electrode arranged in conductive liquid and generating plasma in the vicinity of the negative electrode, and a step for producing conductor fine particles by melting the metal material of the negative electrode and then re-solidifying.

Abstract: A method for producing conductor fine particles in which the advantages of conventional vapor phase method and liquid phase method are utilized while eliminating the drawbacks of both methods remarkably. Furthermore, definite guidelines and measure for improvement are given to the greatest problems common to the vapor phase method and liquid phase method, i.e., enhancement in quality of the unit fine particle and a fine particle production method controllably temporarily and regionally. The method for producing conductor fine particles comprises a step for applying a voltage to a pair of electrode consisting of a positive electrode and a negative electrode arranged in conductive liquid and generating plasma in the vicinity of the negative electrode, and a step for producing conductor fine particles by melting the metal material of the negative electrode and then re-solidifying.