What question did this study set out to answer?

This research aims to understand how long it takes for a Langmuir probe's sheath to stabilize in response to background pressure changes.

May 8, 2026Open Access

Langmuir probe sheath size dynamics under medium pressure

Key Points

This research aims to understand how long it takes for a Langmuir probe's sheath to stabilize in response to background pressure changes.
Utilized a 2D3V particle model of low-temperature plasma under an external electric field.
Developed an algorithm to characterize sheath radius and transition times after potential changes.
Assessed stabilization rates of sheath radius and probe current.
Sheath radius stabilization occurs at a rate faster than or equal to probe current stabilization.
Transition times align well with a model based on ion mobility.
Sheath radius can expand up to twice its initial size during stabilization.

Abstract

This study investigates the time required for the stabilization of the sheath of a cylindrical Langmuir probe as a function of background pressure using a 2D3V particle model of low-temperature plasma under an external electric field. We present an algorithm for the characterization of the sheath radius and calculate the transition time of the sheath radius after a sudden change of the probe potential. The observed transition times in collisional plasmas are well described by a model based on the ion mobility. In general, the sheath radius stabilizes at a rate that is faster than or equal to the rate of probe current stabilization. The radius of the sheath potential expands up to twice during the stabilization.

Langmuir probe sheath size dynamics under medium pressure

Key Points

Abstract

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