An explosive mixture compositionally comprises a powdered deuteride of an alkaline earth metal or alkali metal mixed with a catalytic mixture, wherein said catalytic mixture comprises red phosphorous powder and a transition metal powder from Period 4 or Period 5 of the Periodic table.

A method and an apparatus are provided for performing a fusion reaction. The method comprises providing neutral gas within a gas chamber, supplying energy to the gas chamber to initiate heating of a cathode and ionization of the neutral gas into protons and electrons, causing formation of a conducting channel due to the ionized neutral gas, causing formation of an electron layer outside the cathode based on set of thermionically emitted electrons by the heated cathode, causing acceleration of the electrons towards the cathode to cause the heated cathode to emit a set of secondary electrons due to a potential associated with the electron layer. The set of secondary electrons enhance strength of the electron layer. The method comprises causing formation of an electrostatic potential profile with dips and peaks, due to an electron-ion two-stream instability. The protons are accelerated towards the cathode at peaks and bombardment of the protons into the cathode enables fusion reaction.

An energy amplification agent 6 is supplied into a reactor 1 to generate fine particles of the agent 6 inside of the heated reactor by vaporizing the agent, and, then, the fine particles are ionized by electromagnetic waves to form a plasma space 5 including a combination of atoms of the fine particles, ions and electrons in which the fine particles themselves are decayed in plasma to be separated into protons, neutrons and electrons by electromagnetic waves in shape of standing waves emitted from a wall surface 1a and large-strength electromagnetic waves generated at an uncertain period through amplification functions of the fine particles, so that hydrogen is obtained, and heat is obtained in such a manner that protons and neutrons are mainly reunited with each other in a plasma atmosphere after the plasma decay when gas to be treated is supplied into the plasma space.

Articles of manufacture, machines, processes for using the articles and machines, processes for making the articles and machines, and products produced by the process of making, along with necessary intermediates, directed to mixed nuclear power conversion.

A controlled fusion process is provided that can produce a sustained series of fusion reactions: a process that (i) uses a substantially higher reactant density of the deuterium and tritium gases by converging cationic reactants into the higher reaction density at a target cathode rather than relying on random collisions, the converging producing a substantially higher rate of fusion and energy production; (ii) uses a substantially lower input of energy to initiate the fusion; (iii) can be cycled at a substantially higher cycle frequency; (iv) has a practical heat exchange method; (v) is substantially less costly to manufacture, operate, and maintain; and, (vi) has a substantially improved reaction efficiency as a result of not mixing reactants with products.

Methods, apparatuses, devices, and systems for creating, controlling, conducting, and optimizing fusion activities of nuclei. The controlled fusion activities cover a spectrum of reactions from aneutronic, fusion reactions that produce essentially no neutrons, to neutronic, fusion reactions that produce substantial numbers of neutrons.

Methods, apparatuses, devices, and systems for creating, controlling, conducting, and optimizing fusion activities of nuclei. The controlled fusion activities cover a spectrum of reactions from aneutronic, fusion reactions that produce essentially no neutrons, to neutronic, fusion reactions that produce substantial numbers of neutrons.

Methods, apparatuses, devices, and systems for creating, controlling, conducting, and optimizing fusion activities of nuclei. The controlled fusion activities cover a spectrum of reactions from aneutronic, fusion reactions that produce essentially no neutrons, to neutronic, fusion reactions that produce substantial numbers of neutrons.

The present disclosure provides methods and systems for generating heat from nuclear fusion. The methods and systems utilize host materials (such as metal nanoparticles) to host fusionable materials (such as deuterium). The host materials and/or fusionable materials are irradiated with electromagnetic radiation that induces phonon vibrations in the host material and/or fusionable materials. The phonon vibrations screen the Coulombic repulsion between fusionable material nuclei, thereby increasing a rate of nuclear fusion even at relatively low temperature and pressures. The methods and systems give rise to nuclear fusion reactions which produce energy or heat. The heat may be converted into useful energy using systems and methods for efficient heat dissipation and thermal management.

Fusion reactor designs and techniques are provided in which an electron cyclotron resonance (ECR) system is coupled to a cylindrical reactor to generate ions within the reactor to form a weakly ionized plasma. An ion cyclotron resonance (ICR) system, also coupled to the cylindrical reactor, is further utilized to accelerate the ions radially in the cylindrical reactor with increasing circular trajectory. The ions are contained within a uniform magnetic field provided by a superconducting magnet coupled to the cylindrical reactor. As the ions are accelerated they also drive neutral particles within the reactor to the same energy level through the mechanism of ion-neutral coupling. Collisions of plasma particles with a target also create macroparticles to form a “dusty” plasma, in which the macroparticles contain multiple charges and masses which can sustain fusion reactions.