Ultraheavy Element Enrichment in Impulsive Solar Flares

TL;DR

This paper discusses how cascading Alfven wave turbulence accelerates particles in solar flares, leading to significant enrichment of ultraheavy elements, and explores the implications of turbulence geometry in astrophysical environments.

Contribution

It refines the understanding of particle acceleration and element enrichment in solar flares by incorporating 3D turbulence geometry insights.

Findings

Enrichment of ultraheavy elements observed in impulsive solar flares.

Turbulence damping by particle distributions enhances heavy element acceleration.

The mechanism may apply to other astrophysical turbulence environments.

Abstract

Particle acceleration by cascading Alfven wave turbulence was suggested (Eichler, 1979b) as being responsible for energetic particle populations in $^3$He-rich solar flares. In particular, it was noted that the damping of the turbulence by the tail of the particle distribution in rigidity naturally leads to dramatic enhancement of pre-accelerated species - as $^3$He is posited to be - and superheavy elements. The subsequent detection of large enrichment of ultraheavies, relative to iron, has apparently confirmed this prediction, lending support to the original idea. It is shown here that this picture could be somewhat sharpened by progress in understanding the 3-dimensional geometrical details of cascading Alfven turbulence (Sridhar and Goldreich, 1995). The mechanism may be relevant in other astrophysical environments where the source of turbulence is non-magnetic, such as clusters of galaxies.