Wave heating of the solar atmosphere without shocks

2021

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Context. The origin of the heating of the solar atmosphere is still an unsolved problem. As the photosphere and chromosphere radiate more energy than the solar corona it is challenging but important to reveal all the mechanisms that contribute to plasma heating there. Ion-neutral collisions could play an important role. Aims. Impulsively generated two-fluid magnetoacoustic waves are investigated in the partially ionized solar chromosphere and the associated heating and plasma outflows are studied, which higher up may result in nascent solar wind. Methods. To describe the plasma dynamics, a two-fluid model is applied in which ions+electrons and neutrals are treated as separate fluids. The two-fluid equations are solved numerically using the JOANNA code. Results. We show that magnetoacoustic waves, triggered in the photosphere by localised velocity pulses, can steepen into shocks which heat the chromosphere through ion-neutral collisions. Larger amplitude and wider pulses more effectively heat plasma and generate larger plasma outflows. Rising the altitude at which the pulse is launched, results in opposite effects, mainly in local cooling of the chromosphere, and slower plasma outflows. Conclusions. Even a solitary pulse results in a train of waves. These waves can transform to shock waves and release thermal energy, heating the chromosphere significantly. A pulse can drive vertical flows which higher up can result in the origin of the solar wind.

Section: Numerical Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Chromospheric heating and generation of plasma outflows by impulsively generated two-fluid magnetoacoustic waves

Niedziela

2021

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“…For instance, Soler et al (2019), using a photospheric broadband driver that contains a spectrum of frequencies corresponding to wave periods ranging from 3.33 s up to 2.78 h, in- and Kuźma et al (2020) revealed a rise of the plasma temperature in the solar atmosphere resulting from the collisional heating. The two-fluid effects also play an important role when non-linear effects become important, particularly in the context of wave damping and plasma heating (e.g., Kuźma et al 2019;Wójcik et al 2020;Zhang et al 2021). On top of that, Murawski et al (2020) demonstrated that ion-neutral collisions may solely solve the heating problem of a quiet region of the chromosphere.…”

mentioning

confidence: 99%

3D numerical simulations of propagating two-fluid, torsional Alfvén waves and heating of a partially ionized solar chromosphere

Kuźma

Monthly Notices of the Royal Astronomical Society

2021

We present a new insight into the propagation, attenuation, and dissipation of two-fluid, torsional Alfvén waves in the context of heating of the lower solar atmosphere. By means of numerical simulations of the partially ionized plasma, we solve the set of two-fluid equations for ion plus electron and neutral fluids in 3D Cartesian geometry. We implement initially a current-free magnetic field configuration, corresponding to a magnetic flux-tube that is rooted in the solar photosphere and expands into the chromosphere and corona. We put the lower boundary of our simulation region in the low chromosphere, where ions and neutrals begin to decouple, and implement there a monochromatic driver that directly generates Alfvén waves with a wave period of 30 s. As the ion-neutral drift increases with height, the two-fluid effects become more significant and the energy carried by both Alfvén and magneto-acoustic waves can be thermalized in the process of ion–neutral collisions there. In fact, we observe a significant increase in plasma temperature along the magnetic flux-tube. In conclusion, the two-fluid torsional Alfvén waves can potentially play a role in the heating of the solar chromosphere.

“…( 19) is injected into the simulation domain specified as (−0.08, 0.08) × (−0.5, 60) Mm 2 . We use the JOANNA code (Wójcik et al 2020) to perform the numerical simulations, i.e. to solve the two-fluid equations presented and discussed in the previous section.…”

Section: Numerical Resultsmentioning

confidence: 99%

Solar chromosphere heating and generation of plasma outflows by impulsively generated two-fluid Alfvén waves

Pelekhata

2021

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Context. We address the heating of the solar chromosphere and the related generation of plasma in-and outflows.Aims. We attempt to detect variations in ion temperature and vertical plasma flows, which are driven by impulsively excited two-fluid Alfvén waves. We aim to investigate the possible contribution of these waves on the solar chromosphere heating and plasma outflows. Methods. We perform numerical simulations of the generation and evolution of Alfvén waves with the use of the JOANNA code, which solves the two-fluid equations for ions+electrons and neutrals, coupled by collision terms.Results. We confirm that the damping of impulsively generated small-amplitude Alfvén waves slightly affect the chromosphere's temperature and generate slow plasma flows. In contrast, the Alfvén waves generated by large-amplitude pulses increase the chromospheric plasma temperature more significantly and result in faster plasma outflows. The maximum heating occurs when the pulse is launched from the central photosphere, and the magnitude of the related plasma flows grows with the amplitude of the pulse.Conclusions. Large-amplitude two-fluid Alfvén waves can contribute significantly to the heating of the solar chromosphere and to the generation of plasma outflows.