Coulomb collisional processes in space plasmas; relaxation of suprathermal particle distributions

Kappa distributions received impetus as they provide efficient modelling of the observed particle distributions in space and astrophysical plasmas throughout the heliosphere. This paper presents (i) the connection of kappa distributions with statistical mechanics, by maximizing the associated q-entropy under the constraints of the canonical ensemble within the framework of continuous description; (ii) the derivation of q-entropy from first principles that characterize space plasmas, the additivity of energy, and entropy; and (iii) the derivation of the characteristic first order differential equation, whose solution is the kappa distribution function.

Download Full-text

Spontaneous whistler-cyclotron fluctuations of thermal and non-thermal electron distributions.

10.5194/egusphere-egu2020-22174 ◽

2020 ◽

Author(s):

Pablo S Moya ◽

Daniel Hermosilla ◽

Rodrigo López ◽

Marian Lazar ◽

Stefaan Poedts

Keyword(s):

Strong Dependence ◽

Wave Spectrum ◽

Velocity Distribution Function ◽

Relevant Information ◽

Space Plasmas ◽

Magnetic Fluctuations ◽

Thermal Electron ◽

Particle Distributions ◽

Plasma State ◽

Electron Distributions

<p>Observed particle distributions in space plasmas usually exhibit a variety of non-equilibrium features in the form of temperature anisotropies, suprathermal tails, field aligned beams, etc. The departure from thermal equilibrium provides a source for spontaneous emissions of electromagnetic fluctuations, such as whistler fluctuations at the electron scales. Analysis of these fluctuations provides relevant information about the plasma state and its macroscopic properties. Here we present a comparative analysis of spontaneous fluctuations in plasmas composed by thermal and non-thermal electron distributions. We compare 1.5D PIC simulations of a finite temperature isotropic magnetized electron&#8211;proton plasma modeled with Maxwellian and different kappa velocity distributions. Our results suggest a strong dependence between the shape of the velocity distribution function and the spontaneous magnetic fluctuations wave spectrum. This feature may be used as a proxy to identify the nature of electron populations in space plasmas &#160;at locations where direct in-situ measurements of particle fluxes are not available.</p>

Download Full-text

Space Plasmas: Coupling Between Small and Medium Scale Processes

10.1029/gm086 ◽

1995 ◽

Keyword(s):

Space Plasmas ◽

Medium Scale

Download Full-text

Nonequilibrium Kolmogorov-type particle distributions and their applications

Physics-Uspekhi ◽

10.3367/ufne.0183.201301d.0055 ◽

2013 ◽

Vol 56 (1) ◽

Author(s):

Vladimir E. Zakharov ◽

Vyacheslav I. Karas'

Keyword(s):

Kolmogorov Type ◽

Particle Distributions ◽

Type Particle

Download Full-text

The use of particle monitoring in the performance optimisation of conventional clarification and filtration processes

Water Science & Technology ◽

10.2166/wst.1997.0117 ◽

1997 ◽

Vol 36 (4) ◽

pp. 191-198

Author(s):

G. Standen ◽

P. J. Insole ◽

K. J. Shek ◽

R. A. Irwin

Keyword(s):

Activated Carbon ◽

Water Supply ◽

Laser Diffraction ◽

Raw Water ◽

Particle Distributions ◽

Upper Limit ◽

Start Up ◽

On Line ◽

Particulates Removal ◽

Particle Monitoring

The application of laser diffraction particle monitoring to the performance optimisation of a pilot clarifier and full-scale rapid gravity filters (RGF), operating on water supply works in Hampshire, is described. Furthermore the dosing of powdered activated carbon (PAC) into the works' clarifiers has been evaluated in terms of RGF performance. A costly proposal to install a third filter medium was subsequently abandoned when it was found that particle numbers in the filtered water were consistently below 1×102/ml. Various combinations and doses of coagulants and flocculant aids, shown to give optimum particulates removal during intensive jar testing trials, were transferred to the pilot clarifier. Particle monitoring enabled a more accurate derivation of suitable blanket chemistry and optimum blanket heights than turbidity changes. Raw water turbidities were 10-15 NTU at start-up with corresponding counts beyond the upper limit of the particle monitor. An on-line dilution system was developed to overcome this problem. Latex bead (4.33 μm) and Lycopodium spore (4-5 μm) suspensions (about 1 × 109 particles) were injected into the pilot clarifier to assess the removal efficiency of Cryptosporidium-sized particles. Reductions of about 1.7 log and 2.6 log were achieved for the beads and spores, respectively. Particle distributions of various PAC's and a bentonite were obtained in order to assess their potential effects on the coagulation process during clarification. Bentonite was also beneficial as an on-line means of checking particle monitor response and calibration. The works' filters achieved 1.5 to 2.0 log removals of 2-5 μm particles without media addition or operational changes. Combined clarification and filtration gave better particulates removal than two-stage microfiltration.

Download Full-text

Dispersive MHD waves and alfvenons in charge non-neutral plasmas

Nonlinear Processes in Geophysics ◽

10.5194/npg-15-681-2008 ◽

2008 ◽

Vol 15 (4) ◽

pp. 681-693 ◽

Cited By ~ 3

Author(s):

K. Stasiewicz ◽

J. Ekeberg

Keyword(s):

Soliton Solutions ◽

Theoretical Models ◽

Mhd Waves ◽

Space Plasmas ◽

Charge Effects ◽

Novel Technique ◽

Solitary Structures ◽

Spatial Dimensions ◽

Electric Potentials ◽

Linear And Nonlinear

Abstract. Dispersive properties of linear and nonlinear MHD waves, including shear, kinetic, electron inertial Alfvén, and slow and fast magnetosonic waves are analyzed using both analytical expansions and a novel technique of dispersion diagrams. The analysis is extended to explicitly include space charge effects in non-neutral plasmas. Nonlinear soliton solutions, here called alfvenons, are found to represent either convergent or divergent electric field structures with electric potentials and spatial dimensions similar to those observed by satellites in auroral regions. Similar solitary structures are postulated to be created in the solar corona, where fast alfvenons can provide acceleration of electrons to hundreds of keV during flares. Slow alfvenons driven by chromospheric convection produce positive potentials that can account for the acceleration of solar wind ions to 300–800 km/s. New results are discussed in the context of observations and other theoretical models for nonlinear Alfvén waves in space plasmas.

Download Full-text

General dispersion properties of magnetized plasmas with drifting bi-Kappa distributions. DIS-K: Dispersion Solver for Kappa Plasmas

Journal of Plasma Physics ◽

10.1017/s0022377821000593 ◽

2021 ◽

Vol 87 (3) ◽

Author(s):

R.A. López ◽

S.M. Shaaban ◽

M. Lazar

Keyword(s):

Dominant Role ◽

High Energy ◽

Distribution Functions ◽

Magnetized Plasma ◽

Unstable Wave ◽

Space Plasmas ◽

Good Representation ◽

Particle Interactions ◽

Particle Collisions ◽

Dispersion Tensor

Space plasmas are known to be out of (local) thermodynamic equilibrium, as observations show direct or indirect evidences of non-thermal velocity distributions of plasma particles. Prominent are the anisotropies relative to the magnetic field, anisotropic temperatures, field-aligned beams or drifting populations, but also, the suprathermal populations enhancing the high-energy tails of the observed distributions. Drifting bi-Kappa distribution functions can provide a good representation of these features and enable for a kinetic fundamental description of the dispersion and stability of these collision-poor plasmas, where particle–particle collisions are rare but wave–particle interactions appear to play a dominant role in the dynamics. In the present paper we derive the full set of components of the dispersion tensor for magnetized plasma populations modelled by drifting bi-Kappa distributions. A new solver called DIS-K (DIspersion Solver for Kappa plasmas) is proposed to solve numerically the dispersion relations of high complexity. The solver is validated by comparing with the damped and unstable wave solutions obtained with other codes, operating in the limits of drifting Maxwellian and non-drifting Kappa models. These new theoretical tools enable more realistic characterizations, both analytical and numerical, of wave fluctuations and instabilities in complex kinetic configurations measured in-situ in space plasmas.

Download Full-text