An experimental study of plasma density determination by a cylindrical Langmuir probe at different pressures and magnetic fields in a cylindrical magnetron discharge in heavy rare gases

Passoth, E.; Kudrna, P.; Csambal, C.; Behnke, J. F.; Tichý, M.; Helbig, V.

doi:10.1088/0022-3727/30/12/013

Cited by 86 publications

(69 citation statements)

References 38 publications

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“…The results of the electron density and plasma potential were presented. The model results qualitatively agree with experimental observations [1,8,9,10], further effort in modeling is still needed.…”

Section: Resultssupporting

confidence: 77%

A study of discharge fluctuations in magnetically-supported dc discharge in cylindrical and inverted cylindrical configuration

et al. 2004

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Abstract.We have investigated apparently stochastic fluctuations of magnetically-supported dc discharge in cylindrical coaxial configuration. In the system the electric field had radial direction while the magnetic field was applied axially. The discharge vessel length was 12 centimetres. Working gas was typically argon at pressure of several Pa, magnetic field 10-50 mT.The contribution describes experimental results -frequency and phase analysis of the instabilities, which we detected in our experimental system in both the conventional and inverted magnetron configurations.We bring also 2-D PIC model of the dc discharge under conditions, which can be achieved in the experimental apparatus. The PIC model should answer questions, which originated from the experimental study of the plasma parameters -presented e.g. in [1]. § To whom correspondence should be addressed (bilyk@mbox.troja.mff.cuni.cz)

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Section: Resultssupporting

confidence: 77%

A study of discharge fluctuations in magnetically-supported dc discharge in cylindrical and inverted cylindrical configuration

et al. 2004

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“…However, the magnetic field can lead to electron energy distribution function (EEDF) anisotropy. Passoth 28 determined that EEDF anisotropy depends upon the ratio B/p o , where p o is the pressure in the containment vessel (in this case the discharge chamber). It has been shown experimentally that EEDF anisotropy is negligible for B/p o ≤ 2.5x10 6 G/Torr.…”

Section: Discussionmentioning

confidence: 99%

Discharge Chamber Plasma Structure of a 30 cm NSTAR-type Ion Engine

Herman

Gallimore

2004

40th AIAA/ASME/SAE/ASEE Joint Propulsion Conference and Exhibit

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“…The W foil was oriented such that the planes of each face were perpendicular to the sputtering target face, which minimized both the amount of Cu deposited onto the foil and the effect of the magnetic field on the measured electron current. 27 The height of the probe was adjusted in the chamber so that the W collection area was positioned above the eroded ring or "racetrack," and the center of the probe was placed 1 cm from the surface of the Cu target inside the magnetic trap. A Keithley 2400 source/meter was configured to step voltage in the range of À40 to 14 V and measure the current in mA with a 0.5 s delay between the set point and measurement.…”

Section: Design and Positionmentioning

confidence: 99%

In situ measurements of plasma properties during gas-condensation of Cu nanoparticles

Koten

Voeller

Patterson

et al. 2016

Journal of Applied Physics

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Since the mean, standard deviation, and modality of nanoparticle size distributions can vary greatly between similar input conditions (e.g., power and gas flow rate), plasma diagnostics were carried out in situ using a double-sided, planar Langmuir probe to determine the effect the plasma has on the heating of clusters and their final size distributions. The formation of Cu nanoparticles was analyzed using cluster-plasma physics, which relates the processes of condensation and evaporation to internal plasma properties (e.g., electron temperature and density). Monitoring these plasma properties while depositing Cu nanoparticles with different size distributions revealed a negative correlation between average particle size and electron temperature. Furthermore, the modality of the size distributions also correlated with the modality of the electron energy distributions. It was found that the maximum cluster temperature reached during plasma heating and the material's evaporation point regulates the growth process inside the plasma. In the case of Cu, size distributions with average sizes of 8.2, 17.3, and 24.9 nm in diameter were monitored with the Langmuir probe, and from the measurements made, the cluster temperatures for each deposition were calculated to be 1028, 1009, and 863 K. These values are then compared with the onset evaporation temperature of particles of this size, which was estimated to be 1059, 1068, and 1071 K. Thus, when the cluster temperature is too close to the evaporation temperature, less particle growth occurs, resulting in the formation of smaller particles. V C 2016 AIP Publishing LLC.

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An experimental study of plasma density determination by a cylindrical Langmuir probe at different pressures and magnetic fields in a cylindrical magnetron discharge in heavy rare gases

Cited by 86 publications

References 38 publications

A study of discharge fluctuations in magnetically-supported dc discharge in cylindrical and inverted cylindrical configuration

A study of discharge fluctuations in magnetically-supported dc discharge in cylindrical and inverted cylindrical configuration

Discharge Chamber Plasma Structure of a 30 cm NSTAR-type Ion Engine

In situ measurements of plasma properties during gas-condensation of Cu nanoparticles

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