Kinetic corrections from analytic non-Maxwellian distribution functions in magnetized plasmas

Izacard, Olivier

doi:10.1063/1.4960123

Cited by 10 publications

(39 citation statements)

References 69 publications

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“…The second reason of this failure is the misconception of the fluid reduction from the kinetic Boltzmann description, and more generally of the fluid theory: it has been difficult to expand this fluid theory here for nonequilibria based on the properties of MDFs without falling into the usual limitations, but a summarized point of view of the state-of-the-art of the fluid reduction since the 1870's clarifies our novel approach. The introduced INMDFs represent an extension of the usual fluid theory since (i) it has been shown (Izacard 2016b) The INMDF seems to prove that all accepted misunderstandings about the fluid theory mentioned previously can be bypassed.…”

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confidence: 92%

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Generalized fluid theory including non-Maxwellian kinetic effects

Izacard

2017

J. Plasma Phys.

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The results obtained by the plasma physics community for the validation and the prediction of turbulence and transport in magnetized plasma come mainly from the use of very CPU-consuming particle-in-cell or (gyro)kinetic codes which naturally include non-Maxwellian kinetic effects. To date, fluid codes are not considered to be relevant for the description of these kinetic effects. Here, after revisiting the limitations of the current fluid theory developed in the 19th century, we generalize the fluid theory including kinetic effects such as non-Maxwellian super-thermal tails with as few fluid equations as possible. The collisionless and collisional fluid closures from the nonlinear Landau Fokker-Planck collision operator are shown for an arbitrary collisionality. Indeed, the first fluid models associated with two examples of collisionless fluid closures are obtained by assuming an analytic non-Maxwellian distribution function (e.g., the INMDF [O. Izacard, Phys. Plasmas 23, 082504 (2016) Kinetic corrections from analytic non-Maxwellian distribution functions in magnetized plasmas]). One of the main differences with the literature is our analytic representation of the distribution function in the velocity phase space with as few hidden variables as possible thanks to the use of non-orthogonal basis sets. These new non-Maxwellian fluid equations could initiate the next generation of fluid codes including kinetic effects and can be expanded to other scientific disciplines such as astrophysics, condensed matter, or hydrodynamics. As a validation test, we perform a numerical simulation based on a minimal reduced INMDF fluid model. The result of this test is the discovery of the origin of particle and heat diffusion. The diffusion is due to the competition between a growing INMDF on short time scales due to spatial gradients and the thermalization on longer time scales. The results shown here could draw the breaking of some unsolved understandings of the turbulence.

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confidence: 92%

“…These new parameters have been physically interpreted in Ref. (Izacard 2016b) as a displacement of a population of particles in the velocity phase space due to an external source of energy. The efficiency of the INMDF to describe a localized super-thermal tail is shown in Fig.…”

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confidence: 99%

Generalized fluid theory including non-Maxwellian kinetic effects

Izacard

2017

J. Plasma Phys.

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“…The plausibility of this hypothesis is supported by recent gyrokinetic simulations performed by Churchill et al 22 . Another important factor is the effect of the enhanced suprathermal population on Langmuir probe characteristics [23][24][25][26] : Ďuran et al 27 have shown that a more sophisticated interpretation of probe results can reduce but not eliminate the discrepancy. Resolution of this discrepancy is critical as excessive heat loads could erode and severely limit the lifetimes of the divertor target plates.…”

Section: Introductionmentioning

confidence: 99%

“…n c 75,(26) where n c ∈ [−154, 100] is the cell number counting from the centre of the temperature ramp. Cell size in mfp's was varied between simulations to scan a range of collisionali-…”

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confidence: 99%

Testing nonlocal models of electron thermal conduction for magnetic and inertial confinement fusion applications

et al. 2017

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Three models for nonlocal electron thermal transport are here compared against Vlasov-Fokker-Planck (VFP) codes to assess their accuracy in situations relevant to both inertial fusion hohlraums and tokamak scrape-off layers. The models tested are (i) a moment-based approach using an eigenvector integral closure (EIC) originally developed by Ji, Held, and Sovinec [Phys. Plasmas 16, 022312 (2009)]; (ii) the non-Fourier Landau-fluid (NFLF) model of Dimits, Joseph, and Umansky [Phys. Plasmas 21, 055907 (2014)]; and (iii) Schurtz, Nicolaï, and Busquet’s [Phys. Plasmas 7, 4238 (2000)] multigroup diffusion model (SNB). We find that while the EIC and NFLF models accurately predict the damping rate of a small-amplitude temperature perturbation (within 10% at moderate collisionalities), they overestimate the peak heat flow by as much as 35% and do not predict preheat in the more relevant case where there is a large temperature difference. The SNB model, however, agrees better with VFP results for the latter problem if care is taken with the definition of the mean free path. Additionally, we present for the first time a comparison of the SNB model against a VFP code for a hohlraum-relevant problem with inhomogeneous ionisation and show that the model overestimates the heat flow in the helium gas-fill by a factor of ∼2 despite predicting the peak heat flux to within 16%

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“…The density and velocity distributions in nonequilibrium complex systems have been observed in astronomy and astrophysics, space plasmas, complex fluids, molecular dynamics, nuclear and atomic physics, condensed matter physics, chemical reaction systems, and biological systems. It has been found that the velocity distributions of the charged particles in the systems with long-range correlations are quite far from the Maxwellian distribution, with long energetic tails [1][2]. Recently, nonextensive statistics proposed by Tsallis has attracted great attention of scientific researchers, a new statistics which can study the complex systems beyond thermodynamic equilibrium [3][4].…”

Section: Introductionmentioning

confidence: 99%

Effect of magnetic field on transports of charged particles in the weakly ionized plasma with power-law q-distributions in nonextensive statistics

Wang

2020

Physica A: Statistical Mechanics and its Applications

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By using the generalized Boltzmann equation of transport in nonextensive statistics, we study transport properties of the diffusion flux and the heat flux of charged particles in the weakly ionized plasma with the power-law q-distributions under the magnetic field. We derive the tensor expressions of diffusion coefficient, thermal diffusion coefficient, mobility and thermal conductivity of electrons and ions in the q-distributed plasma under magnetic field. We show that the tensors of the diffusion coefficient, the thermal diffusion coefficient and the thermal conductivity are strongly depend on the q-parameters in nonextensive statistics, and so they are generally not the same as those in the magnetized plasma with a Maxwell distribution.

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Kinetic corrections from analytic non-Maxwellian distribution functions in magnetized plasmas

Cited by 10 publications

References 69 publications

Generalized fluid theory including non-Maxwellian kinetic effects

Generalized fluid theory including non-Maxwellian kinetic effects

Testing nonlocal models of electron thermal conduction for magnetic and inertial confinement fusion applications

Effect of magnetic field on transports of charged particles in the weakly ionized plasma with power-law q-distributions in nonextensive statistics

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