Systems and methods utilizing successive, axially symmetric acceleration and adiabatic compression stages to heat and accelerate two compact tori towards each other and ultimately collide and compress the compact tori within a central chamber. Alternatively, systems and methods utilizing successive, axially asymmetric acceleration and adiabatic compression stages to heat and accelerate a first compact toroid towards and position within a central chamber and to heat and accelerate a second compact toroid towards the central chamber and ultimately collide and merge the first and second compact toroids and compress the compact merge tori within the central chamber.

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.

Described herein is a method of producing energy by proton-boron nuclear fusion, comprising non-thermally igniting a boron nitride nanomaterial (nBN) target by use of a laser emitting a laser beam, wherein the nBN comprises hydrogen. Also described herein is a system for conducting non-thermal ignition proton-boron nuclear fusion, comprising a target comprising hydrogen in a boron nitride nanomaterial (nBN) matrix and a laser positioned to irradiate the target and thereby initiate a nuclear fusion reaction.

An electrochemical power system is provided that generates an electromotive force (EMF) from the catalytic reaction of hydrogen to lower energy (hydrino) states providing direct conversion of the energy released from the hydrino reaction into electricity, the system comprising at least two components chosen from: H.sub.2O catalyst or a source of H.sub.2O catalyst; atomic hydrogen or a source of atomic hydrogen; reactants to form the H.sub.2O catalyst or source of H.sub.2O catalyst and atomic hydrogen or source of atomic hydrogen; and one or more reactants to initiate the catalysis of atomic hydrogen. The electrochemical power system for forming hydrinos and electricity can further comprise a cathode, an anode, reactants that constitute hydrino reactants during cell operation with separate electron flow and ion mass transport, a source of oxygen, and a source of hydrogen. Due to oxidation-reduction electrode reactions, the hydrino-producing reaction mixture is constituted with the migration of electrons through an external circuit and ion mass transport through a separate path such as the electrolyte to complete an electrical circuit. In an embodiment, the anode is regenerated by intermittent charging with the electrodeposition of the anode metal ion from the electrolyte to the anode wherein an anion exchange with the anode metal oxide provides a thermodynamically favorable cycle to facilitate the electrodeposition. A solid fuel power source that provides at least one of thermal and electrical power such as direct electricity or thermal to electricity is further provided that powers a power system comprising (i) at least one reaction cell for the catalysis of atomic hydrogen to form hydrinos, (ii) a chemical fuel mixture comprising at least two components chosen from: a source of H.sub.2O catalyst or H.sub.2O catalyst; a source of atomic hydrogen or atomic hydrogen; reactants to form the source of H.sub.2O catalyst or H.sub.2O catalyst and a source of atomic hydrogen or atomic hydrogen; one or more reactants to initiate the catalysis of atomic hydrogen; and a material to cause the solid fuel to be highly conductive, (iii) at least one set of electrodes that confine the fuel and an electrical power source that provides a short burst of low-voltage, high-current electrical energy to initiate rapid kinetics of the hydrino reaction and an energy gain due to forming hydrinos, (iv) a product recovery systems such as a condenser, (v) a reloading system, (vi) at least one of hydration, thermal, chemical, and electrochemical systems to regenerate the fuel from the reaction products, (vii) a heat sink that accepts the heat from the power-producing reactions, (viii) a

An electrochemical power system is provided that generates an electromotive force (EMF) from the catalytic reaction of hydrogen to lower energy (hydrino) states providing direct conversion of the energy released from the hydrino reaction into electricity, the system comprising at least two components chosen from: H.sub.2O catalyst or a source of H.sub.2O catalyst; atomic hydrogen or a source of atomic hydrogen; reactants to form the H.sub.2O catalyst or source of H.sub.2O catalyst and atomic hydrogen or source of atomic hydrogen; and one or more reactants to initiate the catalysis of atomic hydrogen. The electrochemical power system for forming hydrinos and electricity can further comprise a cathode, an anode, reactants that constitute hydrino reactants during cell operation with separate electron flow and ion mass transport, a source of oxygen, and a source of hydrogen. Due to oxidation-reduction electrode reactions, the hydrino-producing reaction mixture is constituted with the migration of electrons through an external circuit and ion mass transport through a separate path such as the electrolyte to complete an electrical circuit. In an embodiment, the anode is regenerated by intermittent charging with the electrodeposition of the anode metal ion from the electrolyte to the anode wherein an anion exchange with the anode metal oxide provides a thermodynamically favorable cycle to facilitate the electrodeposition. A solid fuel power source that provides at least one of thermal and electrical power such as direct electricity or thermal to electricity is further provided that powers a power system comprising (i) at least one reaction cell for the catalysis of atomic hydrogen to form hydrinos, (ii) a chemical fuel mixture comprising at least two components chosen from: a source of H.sub.2O catalyst or H.sub.2O catalyst; a source of atomic hydrogen or atomic hydrogen; reactants to form the source of H.sub.2O catalyst or H.sub.2O catalyst and a source of atomic hydrogen or atomic hydrogen; one or more reactants to initiate the catalysis of atomic hydrogen; and a material to cause the solid fuel to be highly conductive, (iii) at least one set of electrodes that confine the fuel and an electrical power source that provides a short burst of low-voltage, high-current electrical energy to initiate rapid kinetics of the hydrino reaction and an energy gain due to forming hydrinos, (iv) a product recovery systems such as a condenser, (v) a reloading system, (vi) at least one of hydration, thermal, chemical, and electrochemical systems to regenerate the fuel from the reaction products, (vii) a heat sink that accepts the heat from the power-producing reactions, (viii) a

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.

The engine includes a chamber having an intake and an output for a fluid; a first enclosure configured to contain a source material; a system for at least partially ionizing the source material; and an ion accelerator configured to accelerate the ionized source material towards the chamber so as to cause the fusion of atomic nuclei of the ionized source material with atomic nuclei of the fluid.

Nanoengineered materials are disclosed for Low Energy Nuclear Reactions (LENRs). The nanoengineered materials include quasicrystals and quasicrystal approximants. The energy landscape of these materials is designed to increase a tunneling probability of atoms that participate in a fusion reaction. The nanoengineered materials are designed to have arrangements of atoms in which there are active sites in the material for LENR. The active sites may include networks of double wells designed into the material. In some examples, the design also limits the degrees of freedom for atoms in ways that increase a tunneling probability for tunneling of atoms into sites where fusion occurs.

A method for manipulating fractal forming information, also referred to as ct states, in a dimensional form of increasing and decreasing fractal compression roughly generated by the denominator of pi (fpix), n+1, and the formula 2f(x)^(2^x) including transitional steps between those stepwise increases and decreases by altering the compression of decompression targeting fractal states of the composite dimensional features (next lower dimensional features) or the resulting dimensional features (next higher dimensional features). Steps include identifying the ct states which are to be manipulated, select a compression or decompression ct state component to change the selected ct states, adding the compression or decompression components to yield the new ct states.

A method for manipulating fractal forming information, also referred to as ct states, in a dimensional form of increasing and decreasing fractal compression roughly generated by the denominator of pi (fpix), n+1, and the formula 2f(x)^(2^x) including transitional steps between those stepwise increases and decreases by altering the compression of decompression targeting fractal states of the composite dimensional features (next lower dimensional features) or the resulting dimensional features (next higher dimensional features). Steps include identifying the ct states which are to be manipulated, select a compression or decompression ct state component to change the selected ct states, adding the compression or decompression components to yield the new ct states.