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An atomic hydrogen etching sensor for H2 plasma diagnostics.

D P J van Leuken1, C A de Meijere1, R van der Horst1

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A new method measures atomic hydrogen flux in plasma by tracking amorphous carbon etching. A special "chimney" neutralizes ions, ensuring accurate atomic hydrogen measurements for plasma research.

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Area of Science:

  • Plasma Physics
  • Materials Science

Background:

  • Accurate measurement of atomic hydrogen flux is crucial for understanding and controlling plasma processes.
  • Existing methods for atomic hydrogen detection can be complex or lack selectivity.

Purpose of the Study:

  • To introduce and validate a novel, simple, and selective technique for measuring atomic hydrogen flux in hydrogen plasma environments.
  • To demonstrate the effectiveness of a novel sensor design in suppressing ion interference.

Main Methods:

  • Utilizing the etching rate of an amorphous carbon film as a direct measure of atomic hydrogen flux.
  • Employing a specially designed "chimney" with a bend to neutralize ions through wall collisions.
  • Fabricating the chimney from Macor, a material with low catalytic activity to preserve atomic hydrogen.
  • Deploying the sensor in a radio frequency inductively coupled hydrogen plasma at low pressures (1-10 Pa).

Main Results:

  • The technique successfully measures atomic hydrogen fluxes in the range of 10^19 to 10^21 m^-2 s^-1.
  • Measurements obtained using the carbon etching sensor show agreement within a factor of 4 with heat flux sensors and vacuum ultraviolet absorption spectroscopy.
  • The "chimney" design effectively suppresses ion flux, ensuring that the measured etch rate is dominated by atomic hydrogen.

Conclusions:

  • The developed amorphous carbon etching sensor provides a reliable and selective method for atomic hydrogen flux quantification in plasma.
  • This technique offers a valuable tool for plasma diagnostics and process control in various applications.
  • The sensor's simplicity and effectiveness make it suitable for deployment in diverse plasma environments.