PROPAGATION OF ALFVENIC WAVES FROM CORONA TO CHROMOSPHERE AND CONSEQUENCES FOR SOLAR FLARES

A. J. B. Russell*, L. Fletcher

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

Abstract

How do magnetohydrodynamic waves travel from the fully ionized corona, into and through the underlying partially ionized chromosphere, and what are the consequences for solar flares? To address these questions, we have developed a two-fluid model (of plasma and neutrals) and used it to perform one-dimensional simulations of Alfven waves in a solar atmosphere with realistic density and temperature structure. Studies of a range of solar features (faculae, plage, penumbra, and umbra) show that energy transmission from corona to chromosphere can exceed 20% of incident energy for wave periods of 1 s or less. Damping of waves in the chromosphere depends strongly on wave frequency: waves with periods 10 s or longer pass through the chromosphere with relatively little damping, however, for periods of 1 s or less, a substantial fraction (37%-100%) of wave energy entering the chromosphere is damped by ion-neutral friction in the mid-and upper chromosphere, with electron resistivity playing some role in the lower chromosphere and in umbras. We therefore conclude that Alfvenic waves with periods of a few seconds or less are capable of heating the chromosphere during solar flares, and speculate that they could also contribute to electron acceleration or exciting sunquakes.

Original languageEnglish
Article number81
Number of pages14
JournalAstrophysical Journal
Volume765
Issue number2
DOIs
Publication statusPublished - 10 Mar 2013

Keywords

  • magnetohydrodynamics (MHD)
  • plasmas
  • Sun: chromosphere
  • Sun: corona
  • Sun: flares
  • waves
  • WHITE-LIGHT FLARES
  • HARD X-RAY
  • TEMPERATURE MINIMUM REGION
  • IONIZED PROMINENCE PLASMA
  • ION-NEUTRAL COLLISIONS
  • MAGNETOHYDRODYNAMIC WAVES
  • MAGNETIC RECONNECTION
  • OBSERVATIONAL EVIDENCE
  • CONTINUUM EMISSION
  • LOOP OSCILLATIONS

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