Kinetic features and non-stationary electron trapping in paraxial magnetic nozzles

Sánchez‐Arriaga, G.; Zhou, Jiewei; Ahedo, Eduardo; Martı́nez-Sánchez, Manuel; Ramos, J. J.

doi:10.1088/1361-6595/aaad7f

Cited by 23 publications

(57 citation statements)

References 28 publications

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“…This fact must be taken in to account when comparing convergent-divergent MN models with divergence-only MN models such as those of Refs. [31,34]. In particular, the comparison of the present model with the convergent-only MN of Ref.…”

Section: Introductionmentioning

confidence: 86%

“…Several works on kinetic models consider the plasma expansion in a divergent MN only, placing the plasma source at the throat M (or nearby) [31,36]. This configuration makes full sense when plasma processes on the convergent MN are dominated by phenomena different from magnetic guiding, such as plasma production and heating or interaction with chamber walls.…”

Section: Iii2 Behavior On the Convergent Region And The Mn Throatmentioning

confidence: 99%

“…Each subplot depicts the different terms of the momentum, the total energy, and the perpendicular energy equations for ions and electrons along the nozzle, thus illustrating on the dominant terms in each equation and nozzle region. Concerning plots 6(c)-(d), equation (31) has been used and the constant on its right-hand side has been included into the potential energy term. This is not possible in plots 6(e)-(f) for the flows of perpendicular energy, but units have been set in order that the right-side constant in equation ( 30) is equal to 1.…”

Section: Iv1 the Equivalent Fluid Modelmentioning

confidence: 99%

See 2 more Smart Citations

Macroscopic and parametric study of a kinetic plasma expansion in a paraxial magnetic nozzle

Ahedo

Correyero

Navarro-Cavallé

et al. 2020

Plasma Sources Sci. Technol.

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A kinetic paraxial model of a collisionless plasma stationary expansion in a convergent-divergent magnetic nozzle is analyzed. Monoenergetic and Maxwellian velocity distribution functions of upstream ions are compared, leading to differences in the expansion only on second and higher-order velocity moments. Individual and collective magnetic mirror effects are analyzed. Collective ones are small on the electron population since only a weak temperature anisotropy develops, but they are significant on the ions all over the nozzle. Momentum and energy equations for ions and electrons are assessed based on the kinetic solution. The ion response is different in the hot and cold limits, with the anisotropic pressure tensor being relevant in the first case. Heat fluxes of parallel and perpendicular energies have a dominant role in the electron energy equations. They do not fulfill a Fourier-type law; they are large even when electrons are near isothermal. A crude electron fluid closure based on a constant diffusion-to-convective thermal energy ratio is shown equivalent to the much invoked polytropic law. Analytical dimensionless parameter laws are derived for the nozzle total electric potential fall and the downstream residual electron temperature. Electron confinement and related current control by a thin Debye sheath and a the semi-infinite divergent magnetic nozzle are compared.

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Section: Introductionmentioning

confidence: 86%

Section: Iii2 Behavior On the Convergent Region And The Mn Throatmentioning

confidence: 99%

Section: Iv1 the Equivalent Fluid Modelmentioning

confidence: 99%

See 1 more Smart Citation

Macroscopic and parametric study of a kinetic plasma expansion in a paraxial magnetic nozzle

Ahedo

Correyero

Navarro-Cavallé

et al. 2020

Plasma Sources Sci. Technol.

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“…Incidentally, this model is fully analogous to that of an unmagnetized plasma plume [41]. A posterior time-dependent kinetic paraxial model has demonstrated the formation of trapped populations in the transient period of formation of the MN [32]. This paper attempts to continue these previous modeling efforts by establishing a consis-tent 3D stationary fluid-kinetic model of the MN, which takes advantage when possible of fluid equations and relies on the moments of the collisionless VDF when necessary.…”

Section: Introductionmentioning

confidence: 98%

“…One of them is the total electric potential fall along the MN, which is set by the full expansion of the plasma beam, closely related to the thruster specific impulse and determinant in the interaction between the plasma and the spacecraft wet surfaces. The total potential fall depends again on the electron thermodynamics and also on the ratio of bulk electron current extracted from the plasma source to the thermal electron flux [31,32]. A second one is the plasma detachment from the MN [33], and thus the effective plume divergence angle.…”

Section: Introductionmentioning

confidence: 99%

Three dimensional fluid-kinetic model of a magnetically guided plasma jet

2018

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A fluid-kinetic model of the collisionless plasma flow in a convergent-divergent magnetic nozzle is presented. The model combines the leading-order Vlasov equation and the fluid continuity and perpendicular momentum equation for magnetized electrons, and the fluid equations for cold ions, which must be solved iteratively to determine the self-consistent plasma response in a three-dimensional magnetic field.The kinetic electron solution identifies three electron populations and provides the plasma density and pressure tensor. The far downstream asymptotic behavior shows the anisotropic cooling of the electron populations. The fluid equations determine the electric potential and the fluid velocities. In the small ion-sound gyroradius case the solution is constructed one magnetic line at a time. In the large ion-sound gyroradius case, ion detachment from magnetic lines makes the problem fully three-dimensional.

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Using electron fluid models to analyze plasma thruster discharges

Ahedo

2023

J Electr Propuls

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Fluid models of the slow-dynamics of magnetized, weakly-collisional electrons lead to build computationally-affordable, long-time simulations of plasma discharges in Hall-effect and electrodeless plasma thrusters. This paper discusses the main assumptions and techniques used in 1D to 3D electron fluid models, and some examples illustrate their capabilities. Critical aspects of these fluid models are the expressions for the pressure tensor, the heat flux vector, the plasma-wall fluxes, and the high-frequency-averaged electron transport and heating caused by plasma waves, generated either by turbulence or external irradiation. The different orders of magnitude of the three scalar momentum equations characterize the electron anisotropic transport. Central points of the discussion are: the role of electron inertia, magnetically-aligned meshes versus Cartesian-type ones, the use of a thermalized potential and the infinite mobility limit, the existence of convective-type heat fluxes, and the modeling of the Debye sheath, and wall fluxes. Plasma plume models present their own peculiarities, related to anomalous parallel cooling and heat flux closures, the matching of finite plume domains with quiescent infinity, and solving fully collisionless expansions. Solutions of two 1D electron kinetic models are used to derive kinetically-consistent fluid models and compare them with more conventional ones.

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Kinetic features and non-stationary electron trapping in paraxial magnetic nozzles

Cited by 23 publications

References 28 publications

Macroscopic and parametric study of a kinetic plasma expansion in a paraxial magnetic nozzle

Macroscopic and parametric study of a kinetic plasma expansion in a paraxial magnetic nozzle

Three dimensional fluid-kinetic model of a magnetically guided plasma jet

Using electron fluid models to analyze plasma thruster discharges

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