Confinement Studies in the Columbia Non‐Neutral Torus

Brenner, P. W.; Pedersen, T. S.; Sarasola, Xabier; Hahn, Michael

doi:10.1002/ctpp.200900003

Cited by 6 publications

(4 citation statements)

References 27 publications

(33 reference statements)

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“…The anisotropic tensor would lead to force terms, some along B, usually neglected both in the electron fluid equation and the ideal MHD Ohm's law. Numerical simulations show that > 50% of the electrons are on magnetically trapped orbits, and that there are complicated loss structures in phase space in CNT [31], also consistent with experimental findings [17,32]. The dominant collisional process in these plasmas is electron-neutral collisions, and they are quite rare [17] (ν en ≈ 500 s −1 for η = 0.3).…”

Section: Discussionsupporting

confidence: 77%

First experimental studies of the physics of plasmas of arbitrary degree of neutrality

Sarasola

Pedersen

2012

Plasma Phys. Control. Fusion

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Abstract. The first detailed experimental characterization of the physics of plasmas of arbitrary neutrality is reported. It is shown that the degree of neutralization of the plasma in the Columbia Non-Neutral Torus stellarator can be varied continuously from quasi-neutral to pure electron plasma, and that the plasma can be sustained indefinitely at any degree of neutralization. The physical phenomena change significantly as the degree of neutralization is varied. Quasi-neutral plasmas exhibit a single mode low frequency flute instability. This mode aligns almost perfectly with the magnetic field lines, presenting a resonant m = 3 poloidal structure. For weakly magnetized ions, and moderate degrees of neutralization, multi-mode behaviour is observed, in some cases fully turbulent. At the other extreme of the neutralization scale, electron-rich plasmas with a small but non-negligible amount of ions exhibit single mode fluctuations. Essentially identical phenomena were previously reported by Marksteiner [Q. Marksteiner et al., 2008, Phys. Rev. Lett., 100, 065002]. In addition to the already known poloidal mode number m = 1 of these fluctuations, the toroidal mode number is now known: n = 0. This not only confirms the previous observations that the electron fluid force balance appears to be broken, but the frozen-in flux condition is also violated.

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Section: Discussionsupporting

confidence: 77%

First experimental studies of the physics of plasmas of arbitrary degree of neutrality

Sarasola

Pedersen

2012

Plasma Phys. Control. Fusion

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“…Pure electron plasmas are created in CNT by thermionic emission from heated, negatively biased filaments. A small Debye length is routinely achieved, initially down to 1.5 cm [10,11], and recently 1.0 cm [12], with typical temperatures of T e ≈ 4 eV, densities of n e ≈ 2 × 10 12…”

Section: The Cnt Experimentsmentioning

confidence: 99%

“…Confinement was seen to increase with increasing magnetic field (linearly for rod driven transport, stronger than linearly for neutral collision driven transport) and decrease with neutral pressure (linear relationship between transport rate and neutral pressure) [14]. More recently, τ = 0.32 sec was achieved through reduction of the neutral pressure, maximization of the magnetic field strength, and the installation of a flux surface conforming electrostatic boundary [12]. A moveable emitter was installed, capable of full retraction from the magnetic axis to the edge of the magnetic surface in 20 milliseconds [16], ie.…”

Section: The Cnt Experimentsmentioning

confidence: 99%

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Pure electron plasmas confined for 90 ms in a stellarator without electron sources or internal objects

Brenner

Pedersen

2012

Physics of Plasmas

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We report on the creation and up to 90 millisecond sustainment of pure electron plasmas confined in a stellarator without internal objects. Injection of positrons into such plasmas are expected to lead to the creation of the first electron-positron plasma experiments. These newly created plasmas will also allow a study of pure electron plasmas without the perturbing presence of internal objects.The plasmas were created by thermionic emission of electrons from a heated, biased filament that was retracted in 20 milliseconds. The confinement of these transient plasmas is different from that of steady state plasmas with internal objects and emissive filaments, and is generally shorter, limited by ion buildup. The decay time is increased by lowering the neutral pressure, lowering the electron plasma temperature, or operating with neutrals with high ionization energies (helium). These findings are all consistent with ion accumulation being the cause for the shorter than expected confinement times. The magnetic field strength also moderately increases the decay times. The deleterious effect of ions is not expected to imply a similar deleterious effect when introducing positrons, but it implies that ion accumulation must be avoided also in an electronpositron experiment.

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Initial result of confinement of weakly magnetized lithium ion plasmas in a harmonic potential well of the beam experiment upgrade linear trap

et al. 2016

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This paper presents the initial results of the confinement of weakly magnetized pure lithium ion (Li+) plasmas. Time evolutions of two-dimensional images are successfully investigated for the first time, using an end-on fluorescent screen attached to a micro-channel plate. Simultaneously, the total particle numbers of the Li+ plasmas are obtained from the secondary electron current. Despite the formed Li+ plasma being “kinetic” and the ion density being on the order of the Brillouin density limit, the image on the screen is not disrupted. The confinement occurs over a period of ≈9 s, which is likely to be limited by the conventional diffusion process.

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Confinement Studies in the Columbia Non‐Neutral Torus

Cited by 6 publications

References 27 publications

First experimental studies of the physics of plasmas of arbitrary degree of neutrality

First experimental studies of the physics of plasmas of arbitrary degree of neutrality

Pure electron plasmas confined for 90 ms in a stellarator without electron sources or internal objects

Initial result of confinement of weakly magnetized lithium ion plasmas in a harmonic potential well of the beam experiment upgrade linear trap

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