Yana Maneva scite author profile

Preferential heating and acceleration of heavy ions in the solar wind and corona represent a long-standing theoretical problem in space physics, and are distinct experimental signatures of kinetic processes occurring in collisionless plasmas. We show that fast and slow ion-acoustic waves (IAW) and transverse waves, driven by Alfvén-cyclotron wave parametric instabilities can selectively destroy the coherent fluid motion of different ion species and, in this way lead to their differential heating and acceleration. Trapping of the more abundant protons by the fast IAW generates a proton beam with drift speed of about the Alfvén speed. Because of their larger mass, alpha particles do not become significantly trapped and start, by conservation of total ion momentum, drifting relative to the receding bulk protons. Thus the resulting core protons and the alpha particles are differentially heated via pitch-angle scattering.

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Turbulent heating and acceleration of He⁺⁺ ions by spectra of Alfvén‐cyclotron waves in the expanding solar wind: 1.5‐D hybrid simulations

Maneva

Viñas

Ofman

2013

JGR Space Physics

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[1] Both remote sensing and in situ measurements show that the fast solar wind plasma significantly deviates from thermal equilibrium and is strongly permeated by turbulent electromagnetic waves, which regulate the ion temperature anisotropies and relative drifts. Thus, the ion kinetics is governed by heating and cooling related to absorption and emission of ion-acoustic and ion-cyclotron waves, as well as nonresonant pitch angle scattering and diffusion in phase space. Additionally, the solar wind properties are affected by its nonadiabatic expansion as the wind travels away from the Sun. In this study we present results from 1.5-D hybrid simulations to investigate the effects of a nonlinear turbulent spectrum of Alfvén-cyclotron waves and the solar wind expansion on the anisotropic heating and differential acceleration of protons and He ++ ions. We compare the different heating and acceleration by turbulent Alfvén-cyclotron wave spectra and by pure monochromatic waves. For the waves and the wave spectra used in our model, we find that the He ++ ions are preferentially heated and by the end of the simulations acquire much more than mass-proportional temperature ratios, T˛/T p > m˛/m p . The differential acceleration between the two species strongly depends on the initial wave amplitude and the related spectral index and is often suppressed by the solar wind expansion. We also find that the expansion leads to perpendicular cooling for both species, and depending on the initial wave spectra, it can either heat or cool the ions in parallel direction. Despite the cooling effect of the expansion in perpendicular direction, the wave-particle interactions provide an additional heating source, and the perpendicular temperature components remain higher than the adiabatic predictions.Citation: Maneva, Y. G., A. F. Viñas, and L. Ofman (2013), Turbulent heating and acceleration of He ++ ions by spectra of Alfvén-cyclotron waves in the expanding solar wind: 1.5-D hybrid simulations,

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Multi-fluid Modeling of Magnetosonic Wave Propagation in the Solar Chromosphere: Effects of Impact Ionization and Radiative Recombination

Maneva

Laguna

Lani

et al. 2017

ApJ

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In order to study chromospheric magnetosonic wave propagation including, for the first time, the effects of ionneutral interactions in the partially ionized solar chromosphere, we have developed a new multi-fluid computational modelaccounting for ionization and recombination reactions in gravitationally stratified magnetized collisional media. The two-fluid model used in our 2D numerical simulations treats neutrals as a separate fluid and considers charged species (electrons and ions) within the resistive MHD approach with Coulomb collisions and anisotropic heat flux determined by Braginskiis transport coefficients. The electromagnetic fields are evolved according to the full Maxwell equations and the solenoidality of the magnetic field is enforced with a hyperbolic divergence-cleaning scheme. The initial density and temperature profiles are similar to VAL III chromospheric model in which dynamical, thermal, and chemical equilibrium are considered to ensure comparison to existing MHD models and avoid artificial numerical heating. In this initial setup we include simple homogeneous flux tube magnetic field configuration and an external photospheric velocity driver to simulate the propagation of MHD waves in the partially ionized reactive chromosphere. In particular, we investigate the loss of chemical equilibrium and the plasma heating related to the steepening of fast magnetosonic wave fronts in the gravitationally stratified medium.

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Yana Maneva

Preferential Heating and Acceleration ofαParticles by Alfvén-Cyclotron Waves

Turbulent heating and acceleration of He⁺⁺ ions by spectra of Alfvén‐cyclotron waves in the expanding solar wind: 1.5‐D hybrid simulations

Multi-fluid Modeling of Magnetosonic Wave Propagation in the Solar Chromosphere: Effects of Impact Ionization and Radiative Recombination

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Yana Maneva

Preferential Heating and Acceleration ofαParticles by Alfvén-Cyclotron Waves

Turbulent heating and acceleration of He++ ions by spectra of Alfvén‐cyclotron waves in the expanding solar wind: 1.5‐D hybrid simulations

Multi-fluid Modeling of Magnetosonic Wave Propagation in the Solar Chromosphere: Effects of Impact Ionization and Radiative Recombination

Contact Info

Product

Resources

About

Turbulent heating and acceleration of He⁺⁺ ions by spectra of Alfvén‐cyclotron waves in the expanding solar wind: 1.5‐D hybrid simulations