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Ring-averaged ion velocity distribution function probe for laboratory magnetized plasma experiment.

Eiichirou Kawamori1, Jinting Chen1, Chiahsuan Lin1

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The Review of Scientific Instruments
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Summary

A new diagnostic tool, the ring-averaged ion distribution function probe (RIDFP), measures ion velocity distribution in laboratory plasmas. This probe successfully characterized magnetized plasma, confirming a Maxwellian distribution.

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Area of Science:

  • Plasma Physics
  • Gyrokinetics
  • Diagnostic Techniques

Background:

  • The ring-averaged velocity distribution function of ions is crucial in gyrokinetic plasma physics.
  • Accurate measurement of this distribution is essential for understanding plasma behavior in laboratory settings.

Purpose of the Study:

  • To develop and validate a novel diagnostic tool for measuring the ring-averaged velocity distribution function of ions in laboratory magnetized plasmas.
  • To enable precise characterization of ion velocity distributions, crucial for gyrokinetic studies.

Main Methods:

  • Development of the ring-averaged ion distribution function probe (RIDFP), utilizing a set of ion collectors for velocity selection based on Larmor radii.
  • Implementation of an automated system to adjust the probe's electrostatic potential to match the plasma's space potential, nullifying sheath effects.
  • Deployment of the RIDFP in a laboratory magnetized plasma experiment.

Main Results:

  • The developed RIDFP successfully measured the equilibrium ring-averaged velocity distribution function of ions.
  • The measured distribution was found to be in accordance with a Maxwellian distribution.
  • The ion temperature of the laboratory magnetized plasma was determined to be 0.2 eV.

Conclusions:

  • The RIDFP is a successful diagnostic tool for measuring ion velocity distribution functions in laboratory plasmas.
  • The probe's ability to nullify sheath potential influence ensures accurate measurements.
  • The results validate the probe's capability to characterize plasma equilibrium properties.