Dynamic Spectral Imaging of Decimetric Fiber Bursts in an Eruptive Solar Flare

TL;DR

This study presents the first dynamic spectroscopic imaging of decimetric fiber bursts during a solar flare, revealing their spatial and velocity characteristics, and supporting their association with whistler wave excitation.

Contribution

It provides new imaging observations and 3D reconstructions of fiber burst sources, clarifying their physical origin and relation to flare energy release mechanisms.

Findings

Fiber sources are located near and above flare loop footpoints.

Fiber and background sources are cospatial and share morphology.

Observed properties align with whistler wave excitation models.

Abstract

Fiber bursts are a type of fine structure that is often superposed on type IV radio continuum emission during solar flares. Although studied for many decades, its physical exciter, emission mechanism, and association with the flare energy release remain unclear, partly due to the lack of simultaneous imaging observations. We report the first dynamic spectroscopic imaging observations of decimetric fiber bursts, which occurred during the rise phase of a long-duration eruptive flare on 2012 March 3, as obtained by the Karl G. Jansky Very Large Array in 1--2 GHz. Our results show that the fiber sources are located near and above one footpoint of the flare loops. The fiber source and the background continuum source are found to be cospatial and share the same morphology. It is likely that they are associated with nonthermal electrons trapped in the converging magnetic fields near the footpoint, as supported by a persistent coronal hard X-ray source present during the flare rise phase. We analyze three groups of fiber bursts in detail with dynamic imaging spectroscopy and obtain their mean frequency-dependent centroid trajectories in projection. By using a barometric density model and magnetic field based on a potential-field extrapolation, we further reconstruct the 3-D source trajectories of fiber bursts, for comparison with expectations from the whistler wave model and two MHD-based models. We conclude that the observed fiber burst properties are consistent with an exciter moving at the propagation velocity expected for whistler waves, or models that posit similar exciter velocities.