There is provided a method of producing a localized concentration of energy. The method includes creating at least one shockwave propagating through a non-gaseous medium so as to be incident upon a pocket of gas suspended within the medium. The pocket of gas is spaced from a surface shaped so as, at least partially, to reflect said shockwave in such a way as to direct it onto said gas pocket.

A weakly ionized plasma of ions and neutrals is generated from a first reactant in a confinement region. Orthogonal electric and magnetic fields induce azimuthal rotation of the ions around a longitudinal axis of the confinement region, the azimuthal rotation of the ions imparting azimuthal rotation to the neutrals of the first reactant, and promoting repeated collisions between one or both of the ions and the neutrals with a second reactant. The repeated collisions produce an interaction between the neutrals and the second reactant that produces a product having a nuclear mass that is different from a nuclear mass of any of the nuclei of the neutrals and the second reactant.

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.

A fuel for nuclear fusion where the fusion fuel is compressible for producing fusion with lasers (22) or other means. The fusion fuel comprises a catalytic material mixed with a deuteride of an alkaline earth metal or alkali metal. The catalytic material may comprise a mixture or a compound containing red phosphorus, and a transition metal from Period 4 or Period 5 of the Periodic table. The fusion fuel is cheap and easy to manufacture, and the technology for compression is already available. There is a realistic prospect of commercially producing nuclear fusion energy.

A cavitation heater is an apparatus that implements deuteron fusion in order to produce heat. The apparatus includes a heating chamber, a quantity of heavy water, a piezo-disk antenna, a target foil, a transmission line, a signal generator, and a control unit. The heavy water is retained within the heating chamber and is agitated by the piezo-disk antenna in order to form cavitation bubbles. These cavitation bubbles impact the target foil in order to produce deuteron fusion events that consequently produce heat. The signal generator sends an electrical signal along a transmission line to the piezo-disk antenna in order to dictate how the piezo-disk antenna vibrates within the heavy water. The control unit is used to manage the operational functionalities of the apparatus such as instructing the signal generator to adjust the frequency of the electrical signal.

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.

Methods, apparatuses, devices, and systems for (i) producing and controlling and fusion activities of nuclei, and (ii) heating liquid via heat generated as a result of the fusion activities. 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.

There is provided a method of producing a localized concentration of energy. The method includes creating at least one shockwave propagating through a non-gaseous medium so as to be incident upon a pocket of gas within the medium wherein the pocket of gas is attached to a non-planar surface shaped to concentrate the intensity of the shockwave which is incident upon the pocket of gas.

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.

Enhanced Coulomb repulsion (electron) screening around light element nuclei is achieved by way of utilizing target structures (e.g., nanoparticles) that undergo plasmon oscillation when subjected to electromagnetic (EM) radiation, whereby transient high density electron clouds are produced in localized regions of the target structures during each plasmon oscillation cycle. Each target structure includes an integral body composed of an electrically conductive material that contains light element atoms (e.g., metal hydrides, metal deuterides or metal tritides). The integral body is also configured (i.e., shaped/sized) to undergo plasmon oscillations in response to the applied EM radiation such that the transient high density electron clouds are formed during each plasmon oscillation cycle, whereby brief but significantly elevated charge density variations are generated around light element (e.g., deuterium) atoms located in the localized regions, thereby enhancing Coulomb repulsion screening to enhance nuclear fusion reaction rates. Various target structure compositions and configurations are disclosed.