Expansion rate measurements at moderate pressure of non-neutral electron plasmas in the Electron Diffusion Gauge (EDG) experiment

Morrison, Kyle; Davidson, Ronald C.; Paul, Stephen; Belli, E. A.; Chao, Edward H.

doi:10.1063/1.1374583

Cited by 4 publications

(8 citation statements)

References 33 publications

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“…Malmberg-Penning traps have a uniform magnetic field parallel to the common axis of several cylindrical electrodes, and particles with the same sign of charge can be confined by charging two nonadjacent electrodes to a sufficiently large voltage. Previously reported experimental results [2] from the EDG experiment indicate that the plasma expansion rates measured in the high-vacuum regime (where asymmetry-induced expansion is negligible) are in good agreement with with the predicted expansion rates [13] derived using a warm fluid treatment of the plasma. The evolution of the inferred perpendicular temperature during this expansion, however, did not account for the clear decrease in electrostatic potential energy, prompting improvements to the EDG diagnostic systems.…”

Section: Introductionsupporting

confidence: 67%

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Measurements of Plasma Expansion due to Background Gas in the Electron Diffusion Gauge Experiment

Morrison¹,

Paul²,

Davidson³

2003

AIP Conference Proceedings

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Abstract. The expansion of pure electron plasmas due to collisions with background neutral gas atoms in the Electron Diffusion Gauge experiment device is observed. Measurements of plasma expansion with the new, phosphor-screen density diagnostic suggest that the expansion rates measured previously were observed during the plasma's relaxation to thermal quasi-equilibrium, making it even more remarkable that they scale classically with pressure. Measurements of the on-axis, parallel plasma temperature evolution support the conclusion.

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Section: Introductionsupporting

confidence: 67%

“…Pure electron plasmas are trapped in the Electron Diffusion Gauge (EDG) experiment device [1][2][3][4], a cylindrically symmetric, Malmberg-Penning trap [5][6][7][8][9][10][11][12] with inside diameter I.D. 2 ¡ R w 5.08 cm.…”

Section: Introductionmentioning

confidence: 99%

Measurements of Plasma Expansion due to Background Gas in the Electron Diffusion Gauge Experiment

Morrison¹,

Paul²,

Davidson³

2003

AIP Conference Proceedings

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“…• The diocotron mode can be made to grow in response to electron-neutral collisions without resistive forcing by employing low filament bias voltages that produce a low-density (N L • The sensitivity of mode growth to pressure for P § 10¤ 9 Torr is much greater than that previously observed for mode damping.…”

Section: Diocotron Mode To Filament Conditions and Background Pressurementioning

confidence: 87%

“…The expansion of the plasma column has been related theoretically to the rate of collisions between the electrons and the neutrals [5,6]. The expansion rate has also been measured experimentally on the EDG experiment [7,8] using a Faraday cup collector and observed to scale classically [9] at relatively high neutral pressures (P £ 10¤ 6 ), but this method requires hundreds of repeated discharges to determine the expansion rate. This approach was not only time-consuming, but required excellent plasma reproducibility and low measurement noise.…”

Section: Introductionmentioning

confidence: 99%

Experimental Investigation of m=1 Diocotron Mode Growth at Low Electron Densities

Paul¹,

Morrison²,

Davidson³

2003

AIP Conference Proceedings

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Abstract. Previous experiments on the Electron Diffusion Gauge showed that the diocotron mode damping increases with higher neutral gas filling pressure. Yet the energy dissipated from a rotating plasma by collisions with neutrals is predicted to excite the mode. To resolve this, experiments have been conducted to examine the coupling between expansion and the m=1 diocotron mode. Results from recent experiments have shown interesting phenomena: 1) The degree and sensitivity of mode growth is observed to be strongly dependent on filament conditions. Mode growth rates of nearly 20 sec 1 have been observed even with negligible resistive drive. Specifically, at low filament bias voltages (and correspondingly low electron densities ¡ 1-2 ¢ 10 7 electrons/cm), the mode growth is very sensitive to the heating voltage across the filament, even though changes in filament heating voltage barely affect the plasma expansion, the plasma density profile, the filament emission, or the resulting electron density. 2) At low neutral gas pressure (< 10 9 Torr), the diocotron mode growth rate increases with neutral pressure. However, the growth rate is several orders of magnitude larger than theoretical predictions.

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“…Pure electron plasmas are trapped in the Electron Diffusion Gauge ͑EDG͒ experimental device, [1][2][3][4] a cylindrically symmetric, Malmberg-Penning trap [5][6][7][8][9][10][11][12] with inside diameter I.D.= 2 ϫ R w = 5.08 cm. Malmberg-Penning traps have a uniform magnetic field parallel to the common axis of several cylindrical electrodes, and particles with the same sign of charge can be confined by charging two nonadjacent electrodes to a sufficiently large voltage.…”

Section: Introductionmentioning

confidence: 99%

Electron plasma expansion rate studies on the Electron Diffusion Gauge experimental device

2005

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The expansion of pure electron plasmas due to collisions with background neutral gas atoms in the Electron Diffusion Gauge experimental device is observed to be in good agreement with the predictions of a macroscopic fluid model with uniform electron temperature. Measurements of the expansion with a two-dimensional ͑2-D͒, phosphor-screen density diagnostic suggest that expansion rates measured with the 1-D diagnostic were observed concurrently with substantial changes in the plasma that are not due to electron-neutral collisions. Measurements of the on-axis, parallel plasma temperature evolution support this conclusion and further indicate that the plasmas are continuously losing energy during the expansion, presumably through inelastic collisions with trace background gases.

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Expansion rate measurements at moderate pressure of non-neutral electron plasmas in the Electron Diffusion Gauge (EDG) experiment

Cited by 4 publications

References 33 publications

Measurements of Plasma Expansion due to Background Gas in the Electron Diffusion Gauge Experiment

Measurements of Plasma Expansion due to Background Gas in the Electron Diffusion Gauge Experiment

Experimental Investigation of m=1 Diocotron Mode Growth at Low Electron Densities

Electron plasma expansion rate studies on the Electron Diffusion Gauge experimental device

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