Microarcing instability in RF PECVD plasma system

Y. Yin; M. M.M. Bilek; D. R. McKenzie; R. W. Boswell; C. Charles

doi:10.1016/j.surfcoat.2004.10.089

Microarcing instability in RF PECVD plasma system

Y. Yin^*, M. M.M. Bilek, D. R. McKenzie, R. W. Boswell, C. Charles

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

9 Citations (Scopus)

Abstract

Microarcing at the chamber wall in RF plasma is studied in PECVD type system. A Langmuir probe is used to measure the plasma potential. This system and procedure allows us to create reproducibly microarcings by increasing the plasma potential. The wall arcing threshold of the plasma potential in this system is in the vicinity of 50 V. In this system, the charging process, which is about a few tens of milliseconds or more, is much slower compared to the microsecond discharge. The time constant for sheath charging can be reduced if less sheath area is responsible for the potential recovery. The arcing frequency strongly depends on the plasma potential, the grounded surface area of sheath, and the pressure. This work demonstrated that the microarcing in the RF deposition and reactive etching plasmas depends on plasma potential, gas pressure, surface area of grounded wall, and chamber conditions.

Original language	English
Pages (from-to)	379-383
Number of pages	5
Journal	Surface and Coatings Technology
Volume	198
Issue number	1-3 SPEC. ISS.
DOIs	https://doi.org/10.1016/j.surfcoat.2004.10.089
Publication status	Published - 1 Aug 2005

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10.1016/j.surfcoat.2004.10.089

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title = "Microarcing instability in RF PECVD plasma system",

abstract = "Microarcing at the chamber wall in RF plasma is studied in PECVD type system. A Langmuir probe is used to measure the plasma potential. This system and procedure allows us to create reproducibly microarcings by increasing the plasma potential. The wall arcing threshold of the plasma potential in this system is in the vicinity of 50 V. In this system, the charging process, which is about a few tens of milliseconds or more, is much slower compared to the microsecond discharge. The time constant for sheath charging can be reduced if less sheath area is responsible for the potential recovery. The arcing frequency strongly depends on the plasma potential, the grounded surface area of sheath, and the pressure. This work demonstrated that the microarcing in the RF deposition and reactive etching plasmas depends on plasma potential, gas pressure, surface area of grounded wall, and chamber conditions.",

keywords = "Langmuir probe, Microarcing, RF plasma system",

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T1 - Microarcing instability in RF PECVD plasma system

AU - Yin, Y.

AU - Bilek, M. M.M.

AU - McKenzie, D. R.

AU - Boswell, R. W.

AU - Charles, C.

PY - 2005/8/1

Y1 - 2005/8/1

N2 - Microarcing at the chamber wall in RF plasma is studied in PECVD type system. A Langmuir probe is used to measure the plasma potential. This system and procedure allows us to create reproducibly microarcings by increasing the plasma potential. The wall arcing threshold of the plasma potential in this system is in the vicinity of 50 V. In this system, the charging process, which is about a few tens of milliseconds or more, is much slower compared to the microsecond discharge. The time constant for sheath charging can be reduced if less sheath area is responsible for the potential recovery. The arcing frequency strongly depends on the plasma potential, the grounded surface area of sheath, and the pressure. This work demonstrated that the microarcing in the RF deposition and reactive etching plasmas depends on plasma potential, gas pressure, surface area of grounded wall, and chamber conditions.

AB - Microarcing at the chamber wall in RF plasma is studied in PECVD type system. A Langmuir probe is used to measure the plasma potential. This system and procedure allows us to create reproducibly microarcings by increasing the plasma potential. The wall arcing threshold of the plasma potential in this system is in the vicinity of 50 V. In this system, the charging process, which is about a few tens of milliseconds or more, is much slower compared to the microsecond discharge. The time constant for sheath charging can be reduced if less sheath area is responsible for the potential recovery. The arcing frequency strongly depends on the plasma potential, the grounded surface area of sheath, and the pressure. This work demonstrated that the microarcing in the RF deposition and reactive etching plasmas depends on plasma potential, gas pressure, surface area of grounded wall, and chamber conditions.

KW - Langmuir probe

KW - Microarcing

KW - RF plasma system

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DO - 10.1016/j.surfcoat.2004.10.089

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EP - 383

JO - Surface and Coatings Technology

JF - Surface and Coatings Technology

IS - 1-3 SPEC. ISS.

ER -

Microarcing instability in RF PECVD plasma system

Abstract

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