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Fusion devices

Calculate also the activation energy for the reaction, again in kcal/mol, assuming that the Coulomb repulsion maximizes at 3 -y 10 cm separation of the nuclear centers. Assuming a successful cold-fusion device, how many fusions per second would generate one horsepower (1 hp) if the conversion of heat into work were 10% efficient ... [Pg.742]

Helium-3 [14762-55-1], He, has been known as a stable isotope since the middle 1930s and it was suspected that its properties were markedly different from the common isotope, helium-4. The development of nuclear fusion devices in the 1950s yielded workable quantities of pure helium-3 as a decay product from the large tritium inventory implicit in maintaining an arsenal of fusion weapons (see Deuterium AND TRITIUM) Helium-3 is one of the very few stable materials where the only practical source is nuclear transmutation. The chronology of the isolation of the other stable isotopes of the hehum-group gases has been summarized (4). [Pg.4]

The plasma source implantation system does not use the extraction and acceleration scheme found in traditional mass-analy2ing implanters, but rather the sample to be implanted is placed inside a plasma (Fig. 4). This ion implantation scheme evolved from work on controlled fusion devices. The sample is repetitively pulsed at high negative voltages (around 100 kV) to envelope the surface with a flux of energetic plasma ions. Because the plasma surrounds the sample, and because the ions are accelerated normal to the sample surface, plasma-source implantation occurs over the entire surface, thereby eliminating the need to manipulate nonplanar samples in front of the ion beam. In this article, ion implantation systems that implant all surfaces simultaneously are referred to as omnidirectional systems. [Pg.391]

Controlled thermonuclear fusion experiments and certain types of confined arcs known as pinches have temperatures in the 5 x 10 -10 K range. However, to be successhil, controlled thermonuclear fusion needs to take place from 6 x 10 -10 K. In fact, the goal of all fusion devices is to produce high ion temperatures in excess of the electron temperature (10). [Pg.108]

Most modem projectiles and virtually all missiles contain explosives. The plasmas that result from explosives are intrinsic to operation of warheads, bombs, mines, and related devices. Nuclear weapons and plasmas are intimately related. Plasmas are an inevitable result of the detonation of fission and fusion devices and are fundamental to the operation of fusion devices. Compressed pellets, in which a thermonuclear reaction occurs, would be useful militarily for simulation of the effects of nuclear weapons on materials and devices. [Pg.117]

G. M. McCracken, P. E. Stott, and M. W. Thompson, eds.. Plasma Suface Interactions in Controlled Fusion Devices, North-HoUand, Amsterdam, the Nethedands, 1978. [Pg.118]

Also in 1950 Sakliarov and Tamm proposed an idea for a controlled thermonuclear fusion reactor, the TOKAMAK (acronym for the Russian phrase for toroidal chamber with magnetic coiF ), which achieved the highest ratio of output power to input power of any fusion device of the twentieth centuiy. This reactor grew out of interest in a controlled nuclear fusion reaction, since 1950. Sakharov first considered electrostatic confinement, but soon came to the idea of magnetic confinement. Tamm joined the effort with his work on particle motion in a magnetic field, including cyclotron motion, drifts, and magnetic surfaces. Sakharov and Tamm realized that... [Pg.1024]

CVD is used in many experimental coatings for fusion devices. Refractory materials with very high chemical stability and low... [Pg.446]

Water with concentrations between 3 and 20 TU indicates the presence of some tritium from testing of fusion devices and the water probably dates from the first testing period, that is between 1953 and 1961. [Pg.197]

Small-scale, tabletop nuclear fusion devices, known as compact accelerator neutron generators, are routinely used as a source of neutron radiation. By design, however, these devices consume more energy than they release. The beam of neutrons generated by these devices can be used to identify the elemental composition of amaterial.The coal industry uses such beams to measure the sulfur content of coal in real time as the coal moves over conveyor belts. The cement industry similarly uses these beams to judge the quality of cement mixes. These fusiongenerated neutrons are also used to identify the elemental composition of nuclear wastes and for the detection and identification of explosives. [Pg.650]

H-Warhead warhead contg a nuclear fusion device... [Pg.786]

The Surface Chemistry of First-Wall Materials in Magnetic Fusion Devices... [Pg.367]

Figure 1. Diagram of a Tokamak-type fusion device showing the major structural components. Figure 1. Diagram of a Tokamak-type fusion device showing the major structural components.
See other pages where Fusion devices is mentioned: [Pg.117]    [Pg.35]    [Pg.391]    [Pg.405]    [Pg.557]    [Pg.818]    [Pg.451]    [Pg.44]    [Pg.20]    [Pg.412]    [Pg.426]    [Pg.196]    [Pg.264]    [Pg.17]    [Pg.35]    [Pg.48]    [Pg.785]    [Pg.134]    [Pg.117]    [Pg.367]    [Pg.367]    [Pg.368]    [Pg.369]    [Pg.372]    [Pg.373]    [Pg.376]    [Pg.376]    [Pg.383]   
See also in sourсe #XX -- [ Pg.322 ]



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