Fast correlation heating in moderately coupled electron–ion plasmas

Foster, Thomas E.; Fetsch, Henry; Fisch, Nathaniel J.

doi:10.1017/s0022377823000922

Cited by 3 publications

(1 citation statement)

References 101 publications

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“…DIH is not a new phenomenon. It has been studied in great detail in ultracold neutral plasmas [30][31][32][33] and more recently, fusion plasmas [34]. However, it has now been shown that DIH is also expected to occur in atmospheric pressure plasmas [12].…”

Section: Strong Coupling and Dihmentioning

confidence: 99%

Disorder-induced heating in molecular atmospheric pressure plasmas

LeVan,

Acciarri,

Baalrud

2024

Plasma Sources Sci. Technol.

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Recent work has shown that ions are strongly coupled in atmospheric pressure plasmas when the ionization fraction is sufficiently large, leading to a temperature increase from disorder-induced heating that is not accounted for in standard modelling techniques. Here, we extend this study to molecular plasmas. A main finding is that the energy gained by ions in disorder-induced heating gets spread over both translational and rotational degrees of freedom on a nanosecond timescale, causing the final ion and neutral gas temperatures to be lower in the molecular case than in the atomic case. A model is developed for the equilibrium temperature that agrees well with molecular dynamics simulations. The model and simulations are also applied to pressures up to ten atmospheres. We conclude that disorder-induced heating is a significant and predictable phenomena in molecular atmospheric pressure plasmas.

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Section: Strong Coupling and Dihmentioning

confidence: 99%

Disorder-induced heating in molecular atmospheric pressure plasmas

LeVan,

Acciarri,

Baalrud

2024

Plasma Sources Sci. Technol.

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Electron–ion temperature relaxation in nonideal plasmas: High accuracy classical molecular dynamics simulations

Lavrinenko,

Morozov,

Valuev

2024

Contributions to Plasma Physics

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In this work, we prepare a simulation framework for a high‐accuracy numerical study of electron–ion temperature relaxation in nonideal (strongly coupled) plasmas. The existing relaxation rate theories require either parameter selection or some pre‐knowledge of the electron–ion correlation functions and effective interaction potentials. This makes non‐equilibrium classical and quantum molecular dynamics simulations a crucial stage in the study of energy transfer rates. We begin by revisiting the classical molecular dynamics simulations of a system of equally charged particles with different masses on a neutralizing background. We accurately simulate this simple ab‐initio (parameterless) system with controlled precision in terms of number of particles, mass ratio, and energy convergence. The predictions for the equally charged system are compared to the previous simulations and theories, which are reproduced with higher accuracy. We also perform a series of classical molecular dynamics simulations of the system of oppositely charged particles with the corrected Kelbg potential based on the quantum statistical approach. We analyze the differences and similarities between the same‐charge and opposite‐charge systems. Some remarks about the forthcoming application of quantum simulations with the help of WPMD or WPMD‐DFT methods are given.

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Temperature separation under compression of moderately coupled plasma

Fetsch,

Foster,

Fisch

2023

J. Plasma Phys.

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In moderately coupled plasmas, a significant fraction of the internal energy resides in electric fields. As these plasmas are heated or compressed, the shifting partition of energy between particles and fields leads to surprising effects, particularly when ions and electrons have different temperatures. In this work, quasi-equations of state (quasi-EOS) are derived for two-temperature moderately coupled plasma in a thermodynamic framework and expressed in a simple form. These quasi-EOS readily yield expressions for correlation heating, in which heating of the electrons causes a rapid increase in ion temperature even in the absence of collisional energy exchange between species. It is also shown that, remarkably, compression of moderately coupled plasma drives a temperature difference between electrons and ions, even when the species start at equal temperatures. These additional channels for ion heating may be relevant in designing ignition schemes for inertial confinement fusion.

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Fast correlation heating in moderately coupled electron–ion plasmas

Cited by 3 publications

References 101 publications

Disorder-induced heating in molecular atmospheric pressure plasmas

Disorder-induced heating in molecular atmospheric pressure plasmas

Electron–ion temperature relaxation in nonideal plasmas: High accuracy classical molecular dynamics simulations

Temperature separation under compression of moderately coupled plasma

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