Metal sodium (Na) is accommodated, as an amplification agent, into a reaction cylinder 1 which can eject electromagnetic waves by heating it thereby to form a wave energy space in which a high energy is generated intermittently, fine particles of the metal sodium and constituent atoms of gas to be treated being provided with some nuclei each having a vacuum space, the vacuum space being broken by the high energy to absorb the high energy, whereby Dr. NAMBU theory can be applied to a simple and concrete apparatus.

Examples of a modular compression chamber for use in a compression system are disclosed. The modular compression chamber comprises a plurality of individual modules and a plurality of fasteners to attach the plurality of modules in an interlocking fashion to form the chamber. The modules have a pre-determined geometry and size to form a compression chamber with a desired geometry and size. The plurality of fasteners keeps each of the individual modules in compression with neighboring modules so that the formed chamber maintains its integrity during operation. The modules can comprise a plurality of pressure wave generators to generate a pressure wave within the chamber. In one embodiment, the pressure wave generators have a pre-determined geometry and size and are configured to interlock with the neighboring generators forming the individual modules. The fasteners are configured to maintain intimate contact between side walls of the adjacent pressure wave generators.

Embodiments of systems and methods for compressing plasma are described in which plasma pressures above the breaking point of solid material can be achieved by injecting a plasma into a funnel of liquid metal in which the plasma is compressed and/or heated.

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 fields. The controlled fusion activities cover a spectrum of reactions including aneutronic reactions such as proton-boron-11 fusion reactions.

A power generation system comprises: a muon-catalyzed nuclear fusion device configured to undergo muon-catalyzed nuclear fusion; and a nuclear-reactor power generation device configured such that a nuclear fuel therein is irradiated with neutrons generated as a result of muon-catalyzed nuclear fusion in the muon-catalyzed nuclear fusion device, thereby to carry out power generation, wherein a pressurized-water nuclear reaction vessel in the nuclear-reactor power generation device is arranged so as to surround a nuclear fusion reactor core in which muon-catalyzed nuclear fusion occurs via a structural partition separating the muon-catalyzed nuclear fusion device from the nuclear-reactor power generation device.

Disclosed herein is a system for generating neutrons with thermal fusion, composition for use in the same, and method of using the same. The system comprises a crucible, the crucible having a quantum incompressible fluid and a gas bubble therein, a piston having an end submerged within the quantum incompressible fluid, and a controller coupled to the piston configured to drive the piston to generate an acoustic resonance in the quantum incompressible fluid.

A system includes a core, a plurality of tubes, a plurality of gates, and a plurality of compressors. The core defines a plurality of openings. The plurality of tubes extend radially outward from the core. Each tube of the plurality of tubes includes (i) a first end interfacing with one of the plurality of openings and (ii) an opposing second end. Each gate of the plurality of gates is positioned at a respective opening of the plurality of openings of the core such that the plurality of gates are positioned to selectively prevent a backflow of liquid from the core through the plurality of openings and the first end of the plurality of tubes into the plurality of tubes. Each compressor of the plurality of compressors is associated with a respective tube of the plurality of tubes and is positioned at the opposing second end of the respective tube.

A fusion reactor for energy generation by creation of hot and dense plasma suitable for nuclear fusion, including: a high pressure tank defining the external boundary of at least part of a first volume; a solid barrier defining at least part of the boundary between the first volume and a second volume; liquid in a reservoir; at least one pump configured to deliver said liquid from said reservoir into the first volume and to compress it to high pressure in the first volume; fusionable material filling at least part of the second volume; means configured to make said solid barrier penetrable to liquid, allowing liquid flow from the first volume into the second volume.

There is disclosed a system for duality modulation separation of charged particle wave packets comprising a magnet cascade including a plurality of magnets arranged coaxially along a length of a beam path, a beam source coaxially aligned with the magnet cascade at an initial end of the beam path, the beam source providing a selected particle beam projected along the beam path; a particle deflection means located at a point along the beam path beyond the terminal end of a final magnet of the magnet cascade; wherein a selected particle emitted from the beam source travels along the beam path; wherein a significant characteristic fraction of a particle wave packet of the selected particle is an empty wave packet longitudinally separated from a particle-occupied wave packet along the beam path when the system is tuned with characteristic magnetic gradients and a characteristic particle beam velocity for the selected particle type.

A system for producing a localised concentration of energy from an input shockwave includes an amplifier arranged to manipulate one or more of the speed, pressure or shape of an input shockwave. The amplifier comprises a body of a first material, the body defining a cavity for manipulating the input shockwave to produce a manipulated shockwave. The cavity comprises an input for receiving the input shockwave incident upon the amplifier; and an output for outputting a manipulated shock-wave. The system further comprises a target configured to contain fuel, with the amplifier and the target being configured such that the manipulated shockwave is arranged to be output from the amplifier to be incident on the target.