Using Kappa Distributions to Identify the Potential Energy

Livadiotis, G.

doi:10.1002/2017ja024978

Cited by 48 publications

(59 citation statements)

References 69 publications

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“…Despite the above complications, we infer that the calculated polytropic indexes for Saturn's plasma sheet, together with the semiempirical description of the major thermodynamical parameters for both suprathermal H + and O + , can act as an invaluable input in recent models that aim to study the dynamics of Saturn's magnetosphere. In theory‐driven studies, our results can be used in the method provided recently by Livadiotis (), to estimate the dynamical degrees of freedom in a plasma application, through the connection between the κ ‐index and the polytropic index.…”

Section: Discussion: Plasma Sheet Thermodynamic Statementioning

confidence: 97%

Energetic Ion Moments and Polytropic Index in Saturn's Magnetosphere using Cassini/MIMI Measurements: A Simple Model Based on κ‐Distribution Functions

et al. 2018

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Moments of the charged particle distribution function provide a compact way of studying the transport, acceleration, and interactions of plasma and energetic particles in the magnetosphere. We employ -distributions to describe the energy spectra of H + and O + , based on >20 keV measurements by the three detectors of Cassini's Magnetospheric Imaging Instrument, covering the time period from DOY 183/2004 to 016/2016, 5 < L < 20. From the analytical spectra we calculate the equatorial distributions of energetic ion moments inside Saturn's magnetosphere and then focus on the distributions of the characteristic energy (E c = I E ∕I n ), temperature, and -index of these ions. A semiempirical model is utilized to simulate the equatorial ion moments in both local time and L-shell, allowing the derivation of the polytropic index (Γ) for both H + and O + . Primary results are as follows: (a) The ∼9 < L < 20 region corresponds to a local equatorial acceleration region, where subadiabatic transport of H + (Γ ∼1.25) and quasi-isothermal behavior of O + (Γ ∼0.95) dominate the ion energetics; (b) energetic ions are heavily depleted in the inner magnetospheric regions, and their behavior appears to be quasi-isothermal (Γ <1); (c) the (quasi-) periodic energetic ion injections in the outer parts of Saturn's magnetosphere (especially beyond 17-18 R S ) produce durable signatures in the energetic ion moments; (d) the plasma sheet does not seem to have a ground thermodynamic state, but the extended neutral gas distribution at Saturn provides an effective cooling mechanism that does not allow the plasma sheet to behave adiabatically.

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Section: Discussion: Plasma Sheet Thermodynamic Statementioning

confidence: 97%

Energetic Ion Moments and Polytropic Index in Saturn's Magnetosphere using Cassini/MIMI Measurements: A Simple Model Based on κ‐Distribution Functions

et al. 2018

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“…The kappa distributions have a tremendous number of applications in space and astrophysical plasmas, such as the inner heliosphere, including solar wind (e.g., [13,20,26,[38][39][40][41][42][43][44][45][46][47][48]), solar spectra (e.g., [49,50]), the solar corona (e.g., [51][52][53][54]), solar energetic particles (e.g., [55,56]), corotating interaction regions (e.g., [57]), and related solar flares (e.g., [21,33,58,59]); planetary magnetospheres, including the magnetosheath (e.g., [60,61]), magnetopause (e.g., [62]), magnetotail (e.g., [63]), ring current (e.g., [64]), plasma sheet (e.g., [65][66][67]), magnetospheric substorms (e.g., [68]), Aurora (e.g., [69]); magnetospheres of giant planets like the Jovian (e.g., [70][71][72]), Saturnian (e.g., [73][74][75][76]), Uranian (e.g., [77]), and Neptunian (e.g., <...>…”

Section: Discussion: Applications and Physical Insightsmentioning

confidence: 99%

“…Both the Maxwellian core and power-law tail can support useful techniques for finding the values of temperature and kappa. Some examples are the methods of exploiting the Maxwellian behavior of kappa distributions at the core [26,27,117] and the power-law behavior of kappa distributions at the tail [88][89][90]. Nevertheless, care must be shown when using power-laws in general.…”

Section: Discussion: Applications and Physical Insightsmentioning

confidence: 99%

“…There are various mechanisms capable of generating kappa distributions in space and astrophysical plasmas. Some examples are superstatistics [15][16][17][18], the effect of shock waves [19], weak turbulence [20], turbulence with a diffusion coefficient inversely proportional to velocity [21], the effect of pickup ions [22], pump acceleration mechanism [23], and polytropic behavior [24][25][26]; (see also [1], chapters 5, 6, 8, 10, 15, and 16). Also, common processes characteristic of space plasmas, such as the Debye shielding and magnetic coupling, have an important role in the generation of kappa distributions in plasmas [27].…”

Section: Introductionmentioning

confidence: 99%

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Kappa Distributions: Statistical Physics and Thermodynamics of Space and Astrophysical Plasmas

Livadiotis

2018

Universe

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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.

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“…Surely, this is far from the characterization of space plasmas where 10 8 < <N D < <10 12 . [11] The kappa distributions have become increasingly widespread across the physics of space plasmas, describing particles in the heliosphere, from the solar wind and planetary magnetospheres to the heliosheath and beyond, the interstellar and intergalactic plasmas: inner heliosphere, including solar wind, [12][13][14][15][16][17][18][19][20][21][22][23][24][25][26] solar spectra, [27][28][29] solar corona, [30][31][32][33] solar energetic particles, [34,35] corotating interaction regions, [36] and solar flares related; [4,[37][38][39] planetary magnetospheres, including magnetosheath, [40,41] magnetopause, [42] magnetotail, [43] ring current, [44] plasma sheet, [45][46] magnetic reconnection, [47] magnetospheric substorms, [48] Aurora, [49] magnetospheres of giant planets, such as Jovian, [50][51][52]…”

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confidence: 99%

Polytropes in plasmas described by kappa distributions – Application in atmospheric modelling

Livadiotis

2020

Contributions to Plasma Physics

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The paper derives the complete formulations of polytropic behaviour for plasmas described by kappa distributions. This is achieved by employing both positive and negative types of phase-space kappa distributions of a Hamiltonian for a nonzero potential energy, while the cases of positive and negative potential energies are analysed separately. Then, we develop the general polytropic-barometric formula that describes the profiles of density, temperature, and thermal pressure. Furthermore, it is shown how the kappa and polytropic indices can be derived from observational measurements of the temperature altitude gradient. As an example, we calculated the kappa ≈ 3.35 and polytropic ≈ 0.74 indices of the terrestrial atmosphere at ∼100 km, revealing the existence of heating processes that add thermal energy to atmospheric particles. K E Y W O R D S kappa distributions, polytropic index, space plasmas 1 INTRODUCTION Gases and other classical particle systems are characterized by (a) weakly interacting particles, (b) short-range interactions-restricted to particles' first neighbours, (c) absence of any collective-behaviour among particles, and, most important, (d) absence of any local correlations among particles. This last property is certainly related to the former ones, but it is the cornerstone of the basic consideration of the classical Boltzmann-Gibbs statistical mechanics. [1] As a result, when these particle systems reside at thermal equilibrium, they have their phase-space described by the celebrated Maxwell-Boltzmann distribution. On the other hand, the kappa distributions were found to describe particle systems characterized by (a) weakly and/or strongly-interacting particles, (b) short-and/or long-range interactions, (c) collective-behaviour among particles, and again, most important, (d) existence of local correlations among particles. In fact, the kappa index that governs and parameterizes these distributions is inversely related to the correlation coefficient; thus, the higher the value of kappa, the closer we reach the classical limit of Maxwell-Boltzmann distributions, and the smaller the correlation coefficient is among particles. [2,3] Ideal particle systems with all the above properties are the collisionless and weakly coupled plasmas, where the Debye shielding induces local correlations among particles (Figure 1). [4-7] Especially, the space and astrophysical plasmas are such examples of particle systems with correlations described by kappa distributions [8,9] (also, see the book of kappa distributions: [10]). The equation-of-state and the velocity distribution function are two different topics and should not be confused. For instance, in the case of classical plasmas, both the equation-of-state and the velocity distribution function are

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Using Kappa Distributions to Identify the Potential Energy

Cited by 48 publications

References 69 publications

Energetic Ion Moments and Polytropic Index in Saturn's Magnetosphere using Cassini/MIMI Measurements: A Simple Model Based on κ‐Distribution Functions

Energetic Ion Moments and Polytropic Index in Saturn's Magnetosphere using Cassini/MIMI Measurements: A Simple Model Based on κ‐Distribution Functions

Kappa Distributions: Statistical Physics and Thermodynamics of Space and Astrophysical Plasmas

Polytropes in plasmas described by kappa distributions – Application in atmospheric modelling

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