Measurement of the energy distribution of trapped and free electrons in a current-free double layer

K. Takahashi; C. Charles; R. W. Boswell; T. Kaneko; R. Hatakeyama

doi:10.1063/1.2803763

Measurement of the energy distribution of trapped and free electrons in a current-free double layer

K. Takahashi, C. Charles, R. W. Boswell, T. Kaneko, R. Hatakeyama

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91 Citations (Scopus)

Abstract

In the high potential plasma, upstream of the double layer, the measured electron energy distribution function (EEDF) shows a very clear change in slope at energies (εbreak) corresponding to the double layer potential drop. Electrons with lower energy are Maxwellian with a temperature of 8 eV, whereas those with higher energy have a temperature of 5 eV. The EEDF in the downstream plasma has a temperature of 5 eV. Over the range of pressures wherein the double layer and accelerated ion beam are detected by analysis of a retarding field energy analyzer, the strength of the double layer corresponds to the energy where the slope changes in the EEDF (εbreak). We deduce that the downstream electrons come from upstream electrons that have sufficient energy to overcome the potential of the double layer, and that only a single upstream plasma source is required to maintain this phenomenon.

Original language	English
Article number	114503
Journal	Physics of Plasmas
Volume	14
Issue number	11
DOIs	https://doi.org/10.1063/1.2803763
Publication status	Published - 2007

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10.1063/1.2803763

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title = "Measurement of the energy distribution of trapped and free electrons in a current-free double layer",

abstract = "In the high potential plasma, upstream of the double layer, the measured electron energy distribution function (EEDF) shows a very clear change in slope at energies (εbreak) corresponding to the double layer potential drop. Electrons with lower energy are Maxwellian with a temperature of 8 eV, whereas those with higher energy have a temperature of 5 eV. The EEDF in the downstream plasma has a temperature of 5 eV. Over the range of pressures wherein the double layer and accelerated ion beam are detected by analysis of a retarding field energy analyzer, the strength of the double layer corresponds to the energy where the slope changes in the EEDF (εbreak). We deduce that the downstream electrons come from upstream electrons that have sufficient energy to overcome the potential of the double layer, and that only a single upstream plasma source is required to maintain this phenomenon.",

author = "K. Takahashi and C. Charles and Boswell, {R. W.} and T. Kaneko and R. Hatakeyama",

note = "Funding Information: The authors are indebted to Peter Alexander for his technical assistance. This work was supported by Tohoku University 21st COE program, System Construction of Global-Network Oriented Information Electronics, and by the Japan Society for the Promotion of Science for Young Scientists. It was also supported by a Visiting Fellowship of the Research School of Physical Sciences and Engineering. K.T. wishes to thank all the members of the SP3 group of the Plasma Research Laboratory at ANU for their hospitality during his three-month stay, and Dr. C. Charles, Professor R. W. Boswell, and Professor R. Hatakeyama for supervising this project.",

year = "2007",

doi = "10.1063/1.2803763",

language = "English",

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journal = "Physics of Plasmas",

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publisher = "American Institute of Physics",

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T1 - Measurement of the energy distribution of trapped and free electrons in a current-free double layer

AU - Takahashi, K.

AU - Charles, C.

AU - Boswell, R. W.

AU - Kaneko, T.

AU - Hatakeyama, R.

N1 - Funding Information: The authors are indebted to Peter Alexander for his technical assistance. This work was supported by Tohoku University 21st COE program, System Construction of Global-Network Oriented Information Electronics, and by the Japan Society for the Promotion of Science for Young Scientists. It was also supported by a Visiting Fellowship of the Research School of Physical Sciences and Engineering. K.T. wishes to thank all the members of the SP3 group of the Plasma Research Laboratory at ANU for their hospitality during his three-month stay, and Dr. C. Charles, Professor R. W. Boswell, and Professor R. Hatakeyama for supervising this project.

PY - 2007

Y1 - 2007

N2 - In the high potential plasma, upstream of the double layer, the measured electron energy distribution function (EEDF) shows a very clear change in slope at energies (εbreak) corresponding to the double layer potential drop. Electrons with lower energy are Maxwellian with a temperature of 8 eV, whereas those with higher energy have a temperature of 5 eV. The EEDF in the downstream plasma has a temperature of 5 eV. Over the range of pressures wherein the double layer and accelerated ion beam are detected by analysis of a retarding field energy analyzer, the strength of the double layer corresponds to the energy where the slope changes in the EEDF (εbreak). We deduce that the downstream electrons come from upstream electrons that have sufficient energy to overcome the potential of the double layer, and that only a single upstream plasma source is required to maintain this phenomenon.

AB - In the high potential plasma, upstream of the double layer, the measured electron energy distribution function (EEDF) shows a very clear change in slope at energies (εbreak) corresponding to the double layer potential drop. Electrons with lower energy are Maxwellian with a temperature of 8 eV, whereas those with higher energy have a temperature of 5 eV. The EEDF in the downstream plasma has a temperature of 5 eV. Over the range of pressures wherein the double layer and accelerated ion beam are detected by analysis of a retarding field energy analyzer, the strength of the double layer corresponds to the energy where the slope changes in the EEDF (εbreak). We deduce that the downstream electrons come from upstream electrons that have sufficient energy to overcome the potential of the double layer, and that only a single upstream plasma source is required to maintain this phenomenon.

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VL - 14

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Measurement of the energy distribution of trapped and free electrons in a current-free double layer

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