Electric An Electric Power Generation System generates electric power by capturing energy released from transmutation/conversion of one or more chemical element(s) into one or more other element/s, using any one or more elements of the periodic table. The captured energy is converted into electricity in a rector. The system preferably includes a transmutation reactor and an energy capturing system coupled to the reactor that converts captured energy into electricity, and connecting the electric energy to the electric grid or uses it on site power generation. In particular, the energy released in the of transmutation process is directly converted into electric power. Preferably, transmutation products that emerge in the form of charged particles, X-rays and heat, release energy removed from the fusion product ions as they spiral past electrodes of an inverse cyclotron converter.

A nuclear fusion reactor includes a chamber containing plasma and two or more devices which include superconducting electromagnetic coils. At least one of the two or more devices may be biased to a high voltage to provide thermal energy to ions in the magnetic confinement region. In some examples, the chamber and the two or more devices can be coaxial and toroid shaped. In some examples, the chamber can be spherical or cylindrical with the two or more devices being toroid or elongated toroid shaped and formed on opposite faces of a cuboid. The two or more devices may be disposed in the chamber to provide a high-beta magnetic confinement region for the plasma.

A nuclear fusion reactor includes a chamber containing plasma and two or more devices which include superconducting electromagnetic coils. At least one of the two or more devices may be biased to a high voltage to provide thermal energy to ions in the magnetic confinement region. In some examples, the chamber and the two or more devices can be coaxial and toroid shaped. In some examples, the chamber can be spherical or cylindrical with the two or more devices being toroid or elongated toroid shaped and formed on opposite faces of a cuboid. The two or more devices may be disposed in the chamber to provide a high-beta magnetic confinement region for the plasma.

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.

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.

A heat generating device includes a container, a heat generating element disposed inside the container, a heater for heating the heat generating element, a conductive wire part connecting a wall portion of the container and the heater, a hydrogen supply unit for supplying a hydrogen-containing hydrogen-based gas to the heat generating element, and a vacuum evacuation unit for evacuating the container. Formula (1) is satisfied:

A.sub.HCη.sub.eq(T.sub.H−T.sub.W)+A.sub.sε.sub.eqσ(T.sub.S.sup.4−T.sub.W.sup.4)+P.sub.m<H.sub.ex   (1),

where T.sub.H is heater temperature, T.sub.W is external environmental temperature, A.sub.HC is equivalent heat conduction area, k.sub.eq is equivalent thermal conductivity, L.sub.eq is equivalent thermal conduction length, A.sub.S is sample radiation surface area, T.sub.S is sample surface temperature, ε.sub.eq is equivalent emissivity, σ is Stefan-Boltzmann constant, P.sub.m is energy required for maintaining operation, H.sub.ex is thermal energy generated by the heat generating element, and η.sub.eq is (k.sub.eq/L.sub.eq).

A heat generating device includes a container, a heat generating element disposed inside the container, a heater for heating the heat generating element, a conductive wire part connecting a wall portion of the container and the heater, a hydrogen supply unit for supplying a hydrogen-containing hydrogen-based gas to the heat generating element, and a vacuum evacuation unit for evacuating the container. Formula (1) is satisfied:

A.sub.HCη.sub.eq(T.sub.H−T.sub.W)+A.sub.sε.sub.eqσ(T.sub.S.sup.4−T.sub.W.sup.4)+P.sub.m<H.sub.ex   (1),

where T.sub.H is heater temperature, T.sub.W is external environmental temperature, A.sub.HC is equivalent heat conduction area, k.sub.eq is equivalent thermal conductivity, L.sub.eq is equivalent thermal conduction length, A.sub.S is sample radiation surface area, T.sub.S is sample surface temperature, ε.sub.eq is equivalent emissivity, σ is Stefan-Boltzmann constant, P.sub.m is energy required for maintaining operation, H.sub.ex is thermal energy generated by the heat generating element, and η.sub.eq is (k.sub.eq/L.sub.eq).

Methods, apparatuses, devices, and systems for producing and controlling and fusion activities of nuclei. Hydrogen atoms or other neutral species (neutrals) are induced to rotational motion in a confinement region as a result of ion-neutral coupling, in which ions are driven by electric and magnetic fields. The controlled fusion activities cover a spectrum of reactions including aneutronic reactions such as proton-boron-11 fusion reactions.

Methods, apparatuses, devices, and systems for producing and controlling and fusion activities of nuclei. Hydrogen atoms or other neutral species (neutrals) are induced to rotational motion in a confinement region as a result of ion-neutral coupling, in which ions are driven by electric and magnetic fields. The controlled fusion activities cover a spectrum of reactions including aneutronic reactions such as proton-boron-11 fusion reactions.

Systems and methods that facilitate forming and maintaining FRCs with superior stability as well as particle, energy and flux confinement and, more particularly, systems and methods that facilitate forming and maintaining FRCs with elevated system energies and improved sustainment utilizing multi-scaled capture type vacuum pumping.