The invention relates to systems, methods, and devices for imparting energy from dipolar molecules to a circuit in a reactor using electric and magnetic fields. The method as disclosed increases the conductivity of the circuit using dipolar molecules and inducing nuclear fusion to produce heat. The result of the process is to deliver exceptional amounts of controllable energy in an efficient carbon-free manner using an abundant source.

A system for generating photon emission from atomic nuclei includes a device for generating phonons, and a condensed matter medium comprising atomic nuclei. The phonons interact with the atomic nuclei and affect nuclear states of some of the atomic nuclei by transferring energy to the nuclei and causing the nuclei to emit photons. The condensed matter medium includes excited Fe-57* nuclei and ground state Fe-57 nuclei, and the device for generating phonons comprises one of laser irradiation, electric current, diffusion of solutes in solid solutions, or particle beam bombardment.

The invention provides a method for generating a daughter isotope, the method comprising contacting an ion exchange column with parent isotope; allowing the column to equilibrate between the parent and daughter isotopes; eluting the daughter isotope from the column; and repeating the equilibration and elution steps. Also provided is a system for repeatedly generating isotopes from the same support column over time with a single loading of parent isotope, the system comprising a radiation-resistant sorbent column; a parent isotope permanently contained within the column; and a fluid to elute daughter isotope from the column.

The invention provides a method for generating a daughter isotope, the method comprising contacting an ion exchange column with parent isotope; allowing the column to equilibrate between the parent and daughter isotopes; eluting the daughter isotope from the column; and repeating the equilibration and elution steps. Also provided is a system for repeatedly generating isotopes from the same support column over time with a single loading of parent isotope, the system comprising a radiation-resistant sorbent column; a parent isotope permanently contained within the column; and a fluid to elute daughter isotope from the column.

An excitation transfer in a nuclear state is energetically induced. The excitation transfer may be induced by heating a structure to which a nuclear species is mechanically coupled. The heating may be applied as a triangular heat pulse. The heating may generate a stress effect in the structure. The stress effect may produce vibratory phonons. The excitation transfer may include up-conversion. The excitation transfer may include radioactive decay. The decay rate of a radioactive species may be increased to a rate higher than the natural half-life of the radioactive species. Energy may be harnessed from decay of the radioactive species. A decay product having industrial or medical use may be rapidly produced. The decay rate of the radioactive species may be lowered to reduce emissions for safe storage or transportation.

This invention produces electricity, gamma rays, or neutrons, based on the findings set forth in A Nuclear-Gravitational Electrodynamic Framework, Boltzmann's P=e.sup.S/k probability principle, Maxwell's EM theory, Relativity, and Quantum Theory, to optimize protons' pion-electron interactions. Functionally this is like what occurs in Chemical Thermodynamics, using external conditions to control 10.sup.10 m orbital electron interactions to rearrange molecules and obtain desired products, except that this process controls 10.sup.15 m pion-electron interactions by creating an equilibrium between external EM conditions and protons' internal components to control the protons' pion generation.

A system and method for the synthesis of light-nuclei elements (LNEs), including the battery element Lithium, in high-purity form. The method eliminates the need for high-energy proton collision in Cosmic Rays to produce Nitrogen-15. LNEs are produced by placing a mixture with carbon, nitrogen, and oxygen (CNO) source material in a strong, fixed magnetic field, then introducing instability to the CNO's stable isotopes through high-frequency radio waves tuned to the nuclear magnetic resonance (NMR) frequency of a target material in the mixture to produce a LNE product material, and then separating the LNE product material from other materials within the mixture by enhancing gravity separation based on the opposite signs of respective dipole magnetic moments (DMM) to cause attraction of the product material, such as Lithium, to the South magnetic pole away from another product material, such as Beryllium, that is attracted to the North magnetic pole.

A method implements reactions using facilitators and moderators. The method includes filling a reaction vessel with a moderator gas and a facilitator gas. The method further includes triggering a spark in the reaction vessel at a spark gap between a first electrode and a second electrode to generate a product from the facilitator gas and a reactant. The method includes retrieving the product from the reaction vessel through an opening of the reaction vessel.

A method implements reactions using facilitators and moderators. The method includes filling a reaction vessel with a moderator gas and a facilitator gas. The method further includes triggering a spark in the reaction vessel at a spark gap between a first electrode and a second electrode to generate a product from the facilitator gas and a reactant. The method includes retrieving the product from the reaction vessel through an opening of the reaction vessel.

The systems with a combination of a) methods to orient and/or stabilize the radioactive material to a magnetic axis and b) a delivery or reflection method of particles at a specific angle relative to the induced orientation to improve the penetration of said particles past the electrons shell into the nucleus for nuclear decay at a rate faster than the standard half-life calculations or similar reflection methods and systems to redirect decay-expulsion particles back at the preferred angles that increase the target material decay rate. Includes methods of pre-preparation of material, and in production use to extend useful periods of materials such that disposal of used materials deeper in their life when it is already less radioactive.