A nuclear fusion apparatus comprising a tank filled with deuterium and tritium gas mixture, a fast rotating turbine that rotates inside the tank, and a motor to drive the said turbine. The turbine tip moves at a speed larger than the speed of sound of the gas to create shockwaves in the gas. The shockwaves emanate from the turbine tip. The shockwaves are then further compressed by cone-like shaped recessed members or wedge like grooves located near the turbine. The high heat and pressure created by compression of the shockwave create fusion reaction of the gas nuclei. Due to the fast rotation of the turbine and the large number of cone-like shaped members, thousands of small fusion events are created each second. Components are provided to induce resonance in the gas that increase the heat and pressure off the shockwaves.

A plasma compression driver is connected to a plasma containment vessel containing a liquid medium that forms a liquid liner containing plasma, and comprises a pair of coaxially aligned pistons that are sequentially driven towards the liquid liner. A pusher bore containing a pusher piston is coaxial with and has a smaller diameter than a driver bore containing a driver piston such that an interconnecting annular face surface is defined at the junction of the driver and pusher bores. During the compression operation, a prime mover accelerates the driver piston towards the pusher piston and compresses a compression fluid, which accelerates the pusher piston and pushes the liquid medium in the pusher bore into the vessel, causing the liquid liner to collapse, and compressing the plasma. Outward forces on the vessel wall caused by compression driver recoil and increased vessel pressure is counteracted by an inward force applied by the compression fluid on the annular face surface during the compression operation.

A plasma compression driver is connected to a plasma containment vessel containing a liquid medium that forms a liquid liner containing plasma, and comprises a pair of coaxially aligned pistons that are sequentially driven towards the liquid liner. A pusher bore containing a pusher piston is coaxial with and has a smaller diameter than a driver bore containing a driver piston such that an interconnecting annular face surface is defined at the junction of the driver and pusher bores. During the compression operation, a prime mover accelerates the driver piston towards the pusher piston and compresses a compression fluid, which accelerates the pusher piston and pushes the liquid medium in the pusher bore into the vessel, causing the liquid liner to collapse, and compressing the plasma. Outward forces on the vessel wall caused by compression driver recoil and increased vessel pressure is counteracted by an inward force applied by the compression fluid on the annular face surface during the compression operation.

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.

A fusible target is embedded in a high Z liner, ohmically heated and then shock wave heated by implosion of an enveloping high Z liner. The target is adiabatically heated by compression, fusibly ignited and charged-particle heated as it is being ignited. A shock front forms as the liner implodes which shock front detaches from the more slowly moving liner, collides with the outer surface of the target, accelerates inward, rapidly heating the target, adiabatically compressing the target and liner and amplifying the current to converge the liner mass toward a central axis thereby compressing the target to a fusion condition when it begins to ignite and produce charged particles. The charged particles are trapped in a large magnetic field surrounding the target. The energy of the charged particles is deposited into the target to further heat the target to produce an energy gain.

An exothermic transmutation method for at least partially deactivating radioactive material, the method comprising the steps of: —Arranging a dusty compound comprising at least a transition metal in a chamber (7) of a reactor (1) outside a closed container; —Arranging the radioactive material in said chamber (7), the radioactive material being and staying encapsulated in said closed container; —Providing hydrogen in contact with the dusty compound and with the radioactive material at a pressure higher than the ambient pressure; —Generating an electric field in the chamber (7), the electric field being applied to the dusty compound and the radioactive material; —Energizing the dusty compound by heating, then generating a transmutation of said at least one transition metal into another transition metal and proton emission towards the radioactive material, said radioactive material being at least partially deactivated, —Removing thermal energy from the reactor (1).

A magnetic confinement system includes a magnetic mirror device that includes a chamber to hold a target plasma and a coil arrangement to generate a magnetic field configuration in the chamber to confine the target plasma in cylindrically-symmetric form in the chamber, the magnetic field configuration having open ends. The magnetic confinement system further includes plasma guns to generate plasma pistons and project the plasma pistons at the open ends of the magnetic field configuration. In operation, the plasma pistons converge towards each other to close the open ends of the magnetic field configuration and to compress and heat the target plasma.

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 device and a method of heating nano- to micro-scale light absorbent particles within a flashtube designed to sequentially emit intense light, followed by an intense pressure wave. The flashtube device includes a housing and a central filament surrounded by the housing. An inner surface of the housing can be coated with light-scattering particles and/or light-absorbing particles. The filament is generally held in a superconducting state.

The present disclosure provides methods and systems for generating heat from nuclear fusion. The methods and systems can utilize host materials (such as metal nanoparticles) to host fusionable materials (such as deuterium). The host materials and/or fusionable materials can be irradiated with electromagnetic radiation that induces phonon vibrations in the host material and/or fusionable materials. The phonon vibrations can 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 can 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.