Time-resolved plasma properties and eedfs from a rapidly swept 1-MHz Langmuir probe

Summary form only given. Using direct back-to-back high-speed swept Langmuir probe biasing and current measurement, the plasma properties of electron density, electron temperature, plasma potential, floating potential, and the electron energy distribution function are all acquired at a rate of 1-MHz...

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Bibliographic Details
Main Authors: Lobbia, Robert B, Gallimore, Alec D
Format: Conference Proceeding
Language:English
Subjects:
Current measurement
Distribution functions
Electrons
Insulation
Plasma density
Plasma measurements
Plasma properties
Plasma temperature
Probes
Temperature distribution
Online Access:Request full text
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Description
Summary:Summary form only given. Using direct back-to-back high-speed swept Langmuir probe biasing and current measurement, the plasma properties of electron density, electron temperature, plasma potential, floating potential, and the electron energy distribution function are all acquired at a rate of 1-MHz for seamless records in excess of 1-sec. A unique high-speed dual Langmuir probe configuration, consisting of a single Langmuir probe (exposed to plasma) and a null probe (insulated from plasma), enables compensation of the rapidly swept probe signals, thereby permitting probe bias sweep rates in excess of 1-MHz. The time-resolved EEDF data presented are unique from the vast majority of previously published so-called "time-resolved EEDF" data that are actually acquired through phase-averaging and reconstruction of I-V space data (an approach that can only capture one cycle of a periodic plasma process). Thus, the presented approach and data accurately capture the detailed plasma properties (including the EEDF via the Druyvesteyn method) of broadband turbulent plasma behavior inherent to many common laboratory plasmas that exhibit non-quiescent discharges.
ISSN:0730-9244
2576-7208
DOI:10.1109/PLASMA.2010.5534415