Improvement of the floating probe method for ion density and electron temperature measurement without compensation due to voltage reduction across the sheath

The floating probe method (FPM) applicable for processing plasma diagnostics was developed for the measurement of ion density and electron temperature ( J . Appl . Phys . 101 033305). When an AC voltage is applied to a floating probe, harmonic currents are generated due to the nonlinearity of the sh...

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Bibliographic Details
Published in:Plasma sources science & technology 2021-06, Vol.30 (6), p.65006
Main Authors: Lee, Moo-Young, Seo, Jong-In, Eo, Hyundong, Kim, Tae-Woo, Jung, Jiwon, Lim, Yeong-Min, Chung, Chin-Wook
Format: Article
Language:English
Subjects:
DC blocking capacitor
electron temperature
floating probe method
plasma diagnostics
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Summary:The floating probe method (FPM) applicable for processing plasma diagnostics was developed for the measurement of ion density and electron temperature ( J . Appl . Phys . 101 033305). When an AC voltage is applied to a floating probe, harmonic currents are generated due to the nonlinearity of the sheath. The electron temperature and ion density are obtained using the harmonic currents and the voltage across the sheath. However, in the FPM, when the sensing resistance becomes similar to the sheath resistance, iterative calculations must be performed to compensate for the voltage reduction across the sheath due to the sensing resistor. In this paper, the voltage across a DC blocking capacitor is measured to directly obtain the voltage across the sheath. Therefore, it is not necessary to compensate for the voltage reduction across the sheath through iterative calculations. The electron temperature was increasingly overestimated as the capacity of the DC blocking capacitor became smaller. This overestimation was caused by the capacitive load effect and was compensated for using a correction for the second harmonic current. The measured electron temperature and ion density were compared with those from electron energy distribution functions (EEDFs) in an inductively coupled plasma, and they were in good agreement.
ISSN:0963-0252
1361-6595
DOI:10.1088/1361-6595/abff0f