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Main Authors: De Toni, L. B., Ziebell, L. F., Gaelzer, R.
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2411.16333
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author De Toni, L. B.
Ziebell, L. F.
Gaelzer, R.
author_facet De Toni, L. B.
Ziebell, L. F.
Gaelzer, R.
contents This study explores the dynamic evolution of dust electrical potential and plasma particle number densities with a focus on the charging of dust grains through electron and ion absorption, as described by the orbital motion limited (OML) theory. The initial model, which does not account for plasma particle sources and sinks, predicts that dust grains could eventually absorb all plasma particles, leading to a null electrical potential. To address this, we introduced source and sink terms considering a finite region of space in order to simulate real conditions. Our findings indicate that, with the inclusion of plasma particle flow into and out of the region, dust grains reach a stable, non-zero equilibrium potential and the electron and ion densities reach an equilibrium value. This equilibrium is dependent on the size of the region; larger regions result in lower plasma densities and more negative equilibrium potentials. For extensive regions, the dust potential initially mirrors the scenario without sources or sinks but eventually deviates, showing increasing negative values as the region size grows. This behavior is attributed to the electron source term surpassing the combined sink and absorption terms at certain intervals along time evolution.
format Preprint
id arxiv_https___arxiv_org_abs_2411_16333
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Influence of plasma particle flow on dust grain charging and on particle number density
De Toni, L. B.
Ziebell, L. F.
Gaelzer, R.
Plasma Physics
This study explores the dynamic evolution of dust electrical potential and plasma particle number densities with a focus on the charging of dust grains through electron and ion absorption, as described by the orbital motion limited (OML) theory. The initial model, which does not account for plasma particle sources and sinks, predicts that dust grains could eventually absorb all plasma particles, leading to a null electrical potential. To address this, we introduced source and sink terms considering a finite region of space in order to simulate real conditions. Our findings indicate that, with the inclusion of plasma particle flow into and out of the region, dust grains reach a stable, non-zero equilibrium potential and the electron and ion densities reach an equilibrium value. This equilibrium is dependent on the size of the region; larger regions result in lower plasma densities and more negative equilibrium potentials. For extensive regions, the dust potential initially mirrors the scenario without sources or sinks but eventually deviates, showing increasing negative values as the region size grows. This behavior is attributed to the electron source term surpassing the combined sink and absorption terms at certain intervals along time evolution.
title Influence of plasma particle flow on dust grain charging and on particle number density
topic Plasma Physics
url https://arxiv.org/abs/2411.16333