Abstract: Application of axial seed magnetic fields in the range 20-100 T that compress to greater than 10,000 T (100 MG) under typical NIF implosion conditions may significantly relax the conditions required for ignition and propagating burn in NIF ignition targets that are degraded by hydrodynamic instabilities. Such magnetic fields can: (a) permit the recovery of ignition, or at least significant alpha particle heating, in submarginal NIF targets that would otherwise fail because of adverse hydrodynamic instability growth, (b) permit the attainment of ignition in conventional cryogenic layered solid-DT targets redesigned to operate under reduced drive conditions, (c) permit the attainment of volumetric ignition in simpler, room-temperature single-shell DT gas capsules, and (d) ameliorate adverse hohlraum plasma conditions during laser drive and capsule compression. In general, an applied magnetic field should always improve the ignition condition for any NIF ignition target design.

Abstract: Neutrons and multi-neutron particles are generated in a specially configured solid iron electrical solenoid in which photoneutrons from a metallic strip irradiated by laser photons are selectively polarized and fused together. Nuclear binding energy is released by the nuclear reaction. These neutron generators can be joined in a series so that one feeds neutrons into the next neutron generator to increase the output neutron flux density.

Abstract: A nuclear fusion reactor system includes a reactor core containing nuclear fusionable material and a plurality of conducting spheres arranged adjacent each other with at least two of said conducting spheres adjacent the reactor core. The reactor core and the conducting spheres form a electro/magnetic circuit such that fusion of fusionable material in the reactor core establishes an electro/magnetic flow around the electro/magnetic circuit. Preferably, a spherical electromagnetic confinement field is initiated around the reactor core such that fusion of the nuclear fusionable material generates a plasma which interacts with the spherical electromagnetic confinement field in a magnethydrodynamic manner. Preferably, electrical energy is inductively extracted in response to the electro/magnetic flow through a coil arrangement located around at least one of the conducting spheres.

Abstract: A method and apparatus for transporting a positive ion beam to a distant target. An ion channel is created as a path to the target, and the beam injected into the channel at a mildly-relativistic beam velocity. Because the beam is mildly-relativistic, the electric field caused by its positive charge propagates well in advance of the beam, attracting free electrons in the plasma channel and pulling them into the beam along its axis of propagation. The current which is initiated by this precursor electron flow, is sustained during the duration of the beam, and is then a combination of the beam current and additional current carried by the electrons within the channel. As a result, a magnetic flux circulates annularly about the beam of a sufficient magnitude to pinch the beam.

Abstract: A compact fission reactor generates a flux of fission fragments, fission neutrons, and gamma-ray photons. The flux excites a noble element converter medium which produces light. Optical means are provided for focusing the light onto an array of photovoltaic cells. The photovoltaic cells convert the light radiation into electrical energy for various load applications.

Abstract: A method for generating a ballshaped plasma or similar phenomen in a spherical chamber (8), where fuel gases are supplied through the jet nozzles (2a,2b), bringing the plasma ball into rotation. The ionization of the gases is started and maintained by electric discharge and/or laser energy. Magnetic fields are provided through pole pieces (4a,4b,6a,6b), one field of which is rotating in accordance with the plasma ball rotation. A chamber (8) for carrying out the method is also disclosed.

Abstract: A laser protection device employing a gas plasma switch wherein applied laser radiation is focused inside a gas chamber, and a nuclear source is employed to pre-ionize the gas volume, whereupon focused laser radiation causes gas breakdown and plasma formation that attenuates the radiation. Specifically, the invention reduces the threshold of plasma switch initiation by incorporating a nuclear source within the gas chamber that constantly injects plasma forming seed particles into the vicinity of a focused laser beam. The plasma resulting from avalanche ionization of the seed particles reflects, absorbs and deflects the laser radiation. The nuclear source introduces charged particles, excimers and metastable atoms with low ionization potential into the gas chamber. Such charged particles are effective plasma initiators because they have low ionization thresholds. The present invention has been found well suited to protect against pulsed laser sources because of fast rise times and high attenuation levels.

Abstract: Laser sustained discharge apparatus for the production of intense beams of high kinetic energy atomic species. A portion of the plasma resulting from a laser sustained continuous optical discharge which generates energetic atomic species from a gaseous source thereof is expanded through a nozzle into a region of low pressure. The expanded plasma contains a significant concentration of the high kinetic energy atomic species which may be used to investigate the interaction of surfaces therewith. In particular, O-atoms having velocities in excess of 3.5 km/s can be generated for the purpose of studying their interaction with materials in order to develop protective materials for spacecraft which are exposed to such energetic O-atoms during operation in low earth orbit.

Abstract: A plasma containment device for generating and sustaining a ball of plasma therein including an enclosure; a primary electromagnet for generating a primary magnetic field in said enclosure; gas jets positioned at terminal end portions of the primary magnet pole pieces for providing gas under pressure to said enclosure during initial pressurization and for preventing touching contact between electromagnet opposite pole pieces and a plasma ball generated in said enclosure; gas discharge apparatus for selectively sealing said enclosure and for discharging gas from said enclosure; gas ionization apparatus for ionizing gas to form a plasma ball; and plasma energizing apparatus for selectively providing energy to said plasma ball, and for maintaining a large circular electric current in said plasma ball.

Abstract: An Atomic Fusion Device wherein a laser beam is focused to the center of a spherical reaction chamber having a mirrored inner surface. The spherical reaction chamber is evacuated and surrounded by a concentric lithium jacket which is surrounded by a concentric cryogenic jacket in which is immersed a multiaxis Ioffe bar system. A mixture of deuterium and tritium plasma is continuously introduced into the reaction chamber at a metered rate through the preheat units and compressed at the center of the chamber by the electromagnetic field created by the superconductive Ioffe bar system. This mixture is ignited by the laser beam to create a steady-state, self-sustaining lithium blanket. Power is controlled by controlling the plasma input rate and energy is coupled out of the device by electromagnetic coupling or by recirculating the lithium through a heat exchanger.