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When should PIC simulations be applied to atmospheric pressure plasmas? Impact of correlation heating

Acciarri, Marco Daniel ; Moore, Christopher Hudson ; Beving, Lucas Paul ; Baalrud, Scott D.

Plasma sources science & technology, 2024-03, Vol.33 (3) [Periódico revisado por pares]

United States: IOP Publishing

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  • Título:
    When should PIC simulations be applied to atmospheric pressure plasmas? Impact of correlation heating
  • Autor: Acciarri, Marco Daniel ; Moore, Christopher Hudson ; Beving, Lucas Paul ; Baalrud, Scott D.
  • Assuntos: 70 PLASMA PHYSICS AND FUSION TECHNOLOGY ; atmospheric pressure plasmas ; CAPP ; disorder induced heating ; particle in cell ; particle-in-cell simulations, atmospheric pressure plasmas ; PIC ; strong correlations ; strongly coupled
  • É parte de: Plasma sources science & technology, 2024-03, Vol.33 (3)
  • Notas: NA0003525; SC0022201
    SAND-2024-03393J
    USDOE Office of Science (SC), Fusion Energy Sciences (FES)
    USDOE National Nuclear Security Administration (NNSA)
  • Descrição: Molecular dynamics simulations are used to test when the particle-in-cell (PIC) method applies to atmospheric pressure plasmas. It is found that PIC applies only when the plasma density and macroparticle weight are sufficiently small because of two effects associated with correlation heating. The first is the physical effect of disorder-induced heating (DIH). This occurs if the plasma density is large enough that a species (typically ions) is strongly correlated in the sense that the Coulomb coupling parameter exceeds one. In this situation, DIH causes ions to rapidly heat following ionization. PIC is not well suited to capture DIH because doing so requires using a macroparticle weight of one and a grid that well resolves the physical interparticle spacing. These criteria render PIC intractable for macroscale domains. The second effect is a numerical error due to Artificial Correlation Heating (ACH). ACH is like DIH in that it is caused by the Coulomb repulsion between particles, but differs in that it is a numerical effect caused by a macroparticle weight larger than one. Like DIH, it is associated with strong correlations. However, here the macroparticle coupling strength is found to scale as Γ w2/3, where Γ is the physical coupling strength and w is the macroparticle weight. So even if the physical coupling strength of a species is small, as is expected for electrons in atmospheric pressure plasmas, a sufficiently large macroparticle weight can cause the macroparticles to be strongly coupled and therefore heat due to ACH. Furthermore, it is shown that simulations in reduced dimensions exacerbate these issues.
  • Editor: United States: IOP Publishing
  • Idioma: Inglês
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