W.C. Turner scite author profile

We report results of plasma confinement experiments with an auxiliary warm-plasma component flowing along magnetic field lines to suppress ion-cyclotron instabilities. The reduced plasma losses, with the lower fluctuation amplitude, permits neutral-beam buildup of a 13-keV deuterium plasma to densities as high as 4 x 10 13 cm" 3 corresponding to peak beta values of 0.4. Variation of the beam energy demonstrates that longer confinement times are achieved at higher ion energies.

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Investigations of the magnetic structure and the decay of a plasma-gun-generated compact torus

Turner

1983

102

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Thermal-Barrier Production and Identification in a Tandem Mirror

Grubb¹,

Allen²,

Casper³

et al. 1984

Phys. Rev. Lett.

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High-β, Gas-Stabilized, Mirror-Confined Plasma

et al. 1976

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A neutral-beam-sustained plasma in the 2XIIB mirror machine is stabilized by hydrogen gas ionized at one mirror. _Peak plasma energy densities that exceed the energy den-sity_of the vacuum field (P=Sft D E r> /B VSiC 2 ^1) are achieved with deuterons of average energy £ D « 9 keV, peak density 6 D^1 .5xl0 14 cm" 3 , in a magnetic field B vac =0.56 T. These high /3's are sustained for the duration of gas and neutral-beam injection, with no evidence of a £ limit.We report here recent substantial increases in the plasma j3 in the 2XIIB mirror machine, due to stabilization of the neutral-beam-sustained plasma by gas injected in a mirror throat. /3 is defined by p = &nn D E D /B vac 2 , where n D is the central deuterium energy, andB vac is the applied central magnetic field. Previous experiments 1 in the 2XIIB device employed deuterium-loaded titanium-washer guns as sources of cold streaming plasma to suppress ion cyclotron fluctuations caused by the loss-cone nature of the confined ion distribution. 2 A beam-injected plasma j3 =0.4 was achieved with a single gun, limited by periodic bursts of ion cyclotron fluctuations rather than by the available neutral-beam current. 3 Increasing the amount of stabilizing plasma stream with three guns raised j3 to 0.6; again $ was limited by rf bursts. The amount of cold plasma has recently been increased still further by injecting hydrogen gas in a mirror throat. This has resulted in central hot-plasma /3 's exceeding unity, 0>1. This result has significance for mirror fusion reactors, since higher /3's will allow higher fusion power densities for a given field, and may possibly lead to a field-reversed configuration that would enhance the fusion energy balance. 4 The gas-feed system is shown in Fig. 1. A ceramic box is located just beyond one mirror throat of the minimum-B field, with its elliptical apertures conforming to the flux tube passing through a 12-cm-diam circle at the central midplane. Hydrogen or deuterium gas is injected into the box above and below the plasma fan by four pulsed gas valves. The gas is injected with a rise time of ^1 ms, and injection continues for the duration of beam injection (^5 ms) at a rate controlled by orifices at the valve openings inside the box. To start ionization of injected gas, a hot plasma of ft D~2 xl0 13 cm" 3 is initially created in a steady mirror field by beam injection into a streaming plasma target provided by guns located beyond the opposite mirror. 3 Gas neutrals are ionized in the box by electrons (T e »60 eV) coducted along the field from the beam-injected central plasma. The cold ions formed are presumably driven out of the box at the sound speed [v s = (T e /m i ) 1/2 ] by ambipolar electric fields. With sufficient density of cold plasma at the mirror, a small fraction can penetrate the hot central plasma to provide the stabilizing stream after the plasma guns are turned off. 5 During neutral-beam and gas injection, measurements with a microwave interferometer and a Langmuir probe indicate that a dense, cold plasma (n...

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Startup of a Neutral-Beam-Sustained Plasma in a Quasi-dc Magnetic Field

et al. 1976

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W.C. Turner

Stabilization of a Neutral-Beam—Sustained, Mirror-Confined Plasma

Investigations of the magnetic structure and the decay of a plasma-gun-generated compact torus

Thermal-Barrier Production and Identification in a Tandem Mirror

High-β, Gas-Stabilized, Mirror-Confined Plasma

Startup of a Neutral-Beam-Sustained Plasma in a Quasi-dc Magnetic Field

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