Differential kinetic dynamics and heating of ions in the turbulent solar wind

Valentini, F.; Perrone, D.; Stabile, S.; Pezzi, Oreste; Servidio, S.; Marco, R. De; Marcucci, M. F.; Bruno, R.; Lavraud, B.; Keyser, Johan De; Consolini, Giuseppe; Brienza, Daniele; Sorriso‐Valvo, L.; Retinò, Alessandro; Vaivads, A.; Salatti, M.; Veltri, P.

doi:10.1088/1367-2630/18/12/125001

Cited by 64 publications

(98 citation statements)

References 75 publications

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“…The electric and magnetic spectra obtained in the two runs perfectly match, and reveal the typical features observed in solar-wind plasma. Indeed, similarly to previous numerical experiments Valentini et al 2016;Pezzi et al 2018a), an inertial-like range is observed, where the magnetic PSD recalls the Kolmogorov prediction (orange dashed-line) (Kolmogorov 1941), although a proper power-law scaling is not observed due to the limited size of the simulation domain. Around kd p ∼ 1, the usual spectral steepening is recovered (Leamon et al 1998).…”

Section: Evolution Of Turbulence At Proton Scalessupporting

confidence: 86%

Proton–Proton Collisions in the Turbulent Solar Wind: Hybrid Boltzmann–Maxwell Simulations

Pezzi

Perrone

Servidio

et al. 2019

ApJ

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The mechanism of heating for hot, dilute and turbulent plasmas represents a longstanding problem in space physics, whose implications concern both near-Earth environments and astrophysical systems. n order to explore the possible role of inter-particle collisions, simulations of plasma turbulence -in both collisionless and collisional regimehave been compared by adopting Eulerian Hybrid Boltzmann-Maxwell simulations, being proton-proton collisions explicitly introduced through the nonlinear Dougherty operator. Although collisions do not significantly influence the statistical characteristics of the turbulence, they dissipate non-thermal features in the proton distribution function and suppress the enstrophy/entropy cascade in the velocity space, damping the spectral transfer towards large Hermite modes. This enstrophy dissipation is particularly effective in regions where the plasma distribution function is strongly distorted, suggesting that collisional effects are enhanced by fine velocity-space structures. A qualitative connection between the turbulent energy cascade in fluids and the enstrophy cascade in plasmas has been established, opening a new path on the understanding of astrophysical plasma turbulence.

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Section: Evolution Of Turbulence At Proton Scalessupporting

confidence: 86%

Proton–Proton Collisions in the Turbulent Solar Wind: Hybrid Boltzmann–Maxwell Simulations

Pezzi

Perrone

Servidio

et al. 2019

ApJ

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“…Multi-spacecraft and high resolution measurements in the solar wind and in the terrestrial magnetosphere [12,13] have provided evidence of such interconnection [14]. The increasing performance of numerical simulations has also allowed processes on several scales to be examined, and therefore to highlight their relationship [15][16][17][18][19][20][21][22][23][24]. Theoretical efforts are also being carried out in order to highlight the specific processes governing the energy exchange between ranges associated to different regimes [25][26][27].…”

Section: Introductionmentioning

confidence: 99%

Sign Singularity of the Local Energy Transfer in Space Plasma Turbulence

et al. 2019

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2In weakly collisional space plasmas, the turbulent cascade provides most of the energy that is dissipated at small scales by various kinetic processes. Understanding the characteristics of such dissipative mechanisms requires the accurate knowledge of the fluctuations that make energy available for conversion at small scales, as different dissipation processes are triggered by fluctuations of a different nature. The scaling properties of different energy channels are estimated here using a proxy of the local energy transfer, based on the third-order moment scaling law for magnetohydrodynamic turbulence. In particular, the sign-singularity analysis was used to explore the scaling properties of the alternating positive-negative energy fluxes, thus providing information on the structure and topology of such fluxes for each of the different type of fluctuations. The results show the highly complex geometrical nature of the flux, and that the local contributions associated with energy and cross-helicity nonlinear transfer have similar scaling properties. Consequently, the fractal properties of current and vorticity structures are similar to those of the Alfvénic fluctuations. PACS numbers: 94.05.-a, 94.05.Lk, 95.30.Qd

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“…Matthaeus & Lamkin 1986;Biskamp 2008;Servidio et al 2010Servidio et al , 2011Lazarian et al 2012;Karimabadi et al 2013a;Servidio et al 2015;Franci et al 2016;. In this context, currents and coherent structures are typically related to simultaneous enhancement of vorticity, kinetic activity, turbulent transfer and dissipation (e.g., Servidio et al 2012Servidio et al , 2014Karimabadi et al 2013b;Valentini et al 2014Valentini et al , 2016Wan et al 2015;Franci et al 2016;Parashar & Matthaeus 2016;Yang et al 2017;Grošelj et al 2017;Camporeale et al 2018;Sorriso-Valvo et al 2018). Furthermore, reconnection/structures have been recently proved to enhance/trigger the kinetic turbulent cascades in real space Franci et al 2017;Camporeale et al 2018) and also to be related to simultaneous velocity space cascades (Servidio et al 2017;Cerri et al 2018;Pezzi et al 2018).…”

Section: A Broader View: Relevance To Other Instabilities and Turbulementioning

confidence: 99%

Finite-Larmor-radius equilibrium and currents of the Earth’s flank magnetopause

Cerri

2018

J. Plasma Phys.

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We consider the one-dimensional equilibrium problem of a shear-flow boundary layer within an "extended fluid model" of plasma that includes the Hall and the electron pressure terms in the Ohm's law, as well as dynamic equations for anisotropic pressure for each species and first-order finite Larmor radius (FLR) corrections to the ion dynamics. We provide a generalized version of the analytic expressions for the equilibrium configuration given in Cerri et al. (2013), highlighting their intrinsic asymmetry due to the relative orientation of the magnetic field b = B/|B| and the fluid vorticity ω = ∇ × u ("ωb asymmetry"). Finally, we show that FLR effects can modify the Chapman-Ferraro current layer at the flank magnetopause in a way that is consistent with the observed structure reported by Haaland et al. (2014). In particular, we are able to qualitatively reproduce the following key features: (i) the dusk-dawn asymmetry of the current layer, (ii) a double-peak feature in the current profiles, and (iii) adjacent current sheets having thicknesses of several ion Larmor radii and with different current directions.

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Differential kinetic dynamics and heating of ions in the turbulent solar wind

Cited by 64 publications

References 75 publications

Proton–Proton Collisions in the Turbulent Solar Wind: Hybrid Boltzmann–Maxwell Simulations

Proton–Proton Collisions in the Turbulent Solar Wind: Hybrid Boltzmann–Maxwell Simulations

Sign Singularity of the Local Energy Transfer in Space Plasma Turbulence

Finite-Larmor-radius equilibrium and currents of the Earth’s flank magnetopause

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