Revisiting the thermal effect on shock wave propagation in weakly ionized plasmas

Zhou, Qianhong; Yang, Weiping

doi:10.1063/1.4958640

Physics of Plasmas

2016

DOI: 10.1063/1.4958640

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Revisiting the thermal effect on shock wave propagation in weakly ionized plasmas

Qianhong Zhou

Weiping Yang

Abstract: Many researchers have investigated shock propagation in weakly ionized plasmas and observed the following anomalous effects: shock acceleration, shock recovery, shock weakening, shock spreading, and splitting. It was generally accepted that the thermal effect can explain most of the experimental results. However, little attention was paid to the shock recovery. In this paper, the shock wave propagation in weakly ionized plasmas is studied by fluid simulation. It is found that the shock acceleration, weakening,… Show more

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Cited by 3 publications

References 21 publications

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Theory and simulation of shock waves freely propagating through monoatomic non-Boltzmann gas

Döntgen

2024

Theor. Comput. Fluid Dyn.

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The effect of non-Boltzmann energy distributions on the free propagation of shock waves through a monoatomic gas is investigated via theory and simulation. First, the non-Boltzmann heat capacity ratio $$\gamma $$ γ , as a key property for describing shock waves, is derived from first principles via microcanonical integration. Second, atomistic molecular dynamics simulations resembling a shock tube setup are used to test the theory. The presented theory provides heat capacity ratios ranging from the well-known $$\gamma = 5/3$$ γ = 5 / 3 for Boltzmann energy-distributed gas to $$\gamma \rightarrow 1$$ γ → 1 for delta energy-distributed gas. The molecular dynamics simulations of Boltzmann and non-Boltzmann driven gases suggest that the shock wave propagates about 9% slower through the non-Boltzmann driven gas, while the contact wave appears to be about 4% faster if it trails non-Boltzmann driven gas. The observed slowdown of the shock wave through applying a non-Boltzmann energy distribution was found to be consistent with the classical shock wave equations when applying the non-Boltzmann heat capacity ratio. These fundamental findings provide insights into the behavior of non-Boltzmann gases and might help to improve the understanding of gas dynamical phenomena. Graphical abstract

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Theory and simulation of shock waves freely propagating through monoatomic non-Boltzmann gas

Döntgen

2024

Theor. Comput. Fluid Dyn.

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High-frequency counter-flow plasma synthetic jet actuator and its application in suppression of supersonic flow separation

Wang

Jin

et al. 2018

Acta Astronautica

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On analytical approximations for the structure of a shock wave in a fully ionized plasma

Domínguez-Vázquez

Fernández‐Feria

2019

Physics of Plasmas

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Two approximate solutions for the shock wave structure in a fully ionized plasma are given for weak and moderately strong shocks. Both solutions are algebraically very simple in the phase space of the electron and ion temperatures as functions of the plasma velocity, being algebraically more involved in the physical spatial coordinate, except when constant electron conductivity is assumed. One solution is based on the observation that for weak, relaxation shocks, the electron and ion temperatures are very close to each other. However, for sufficiently large ionization (atomic) number Z, this solution is valid even for any difference between both temperatures, capturing quite accurately the ion temperature overshoot appearing in moderately strong relaxation shocks for large Z. For stronger shocks with an internal ion shock, this first approximate solution remains quite accurate in the preheating region upstream of the inner shock but not in the relaxation downstream region. For the latter region, we find another good algebraic approximation based on the almost constancy of the electron entropy. The combination of these two approximations upstream and downstream of the inner shock, connected through the algebraic Rankine-Hugoniot relations for the inner shock, provides a good approximation for the entire shock structure even for moderately strong shocks. These algebraic approximate solutions are compared with exact numerical solutions for several values of the Mach and ionization numbers. Some relevant features such as the shock thickness and the ion temperature overshoot are analyzed.

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Revisiting the thermal effect on shock wave propagation in weakly ionized plasmas

Cited by 3 publications

References 21 publications

Theory and simulation of shock waves freely propagating through monoatomic non-Boltzmann gas

Theory and simulation of shock waves freely propagating through monoatomic non-Boltzmann gas

High-frequency counter-flow plasma synthetic jet actuator and its application in suppression of supersonic flow separation

On analytical approximations for the structure of a shock wave in a fully ionized plasma

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