Ejecta Knot Flickering, Mass Ablation, and Fragmentation in Cassiopeia A

TL;DR

This study uses Hubble Space Telescope images to analyze rapid flickering, ablation tails, and fragmentation of ejecta knots in Cassiopeia A, revealing insights into the interaction between supernova ejecta and the surrounding medium.

Contribution

It provides new observational evidence of ejecta knot flickering, ablation tails, and fragmentation, enhancing understanding of supernova remnant evolution and ejecta-medium interactions.

Findings

Substantial emission variability over nine months.

Detection of ablation tails aligned with knot motion.

Identification of shock-induced knot fragmentation.

Abstract

Ejecta knot flickering, ablation tails, and fragmentation are expected signatures associated with the gradual dissolution of high-velocity supernova (SN) ejecta caused by their passage through an inhomogeneous circumstellar or interstellar medium. Such phenomena mark the initial stages of the gradual merger of SN ejecta with and the enrichment of the surrounding interstellar medium. Here we report on an investigation of this process through changes in the optical flux and morphology of several high-velocity ejecta knots located in the outskirts of the young core-collapse SN remnant Cassiopeia A using {\sl Hubble Space Telescope} images. Examination of WFPC2 F675W and combined ACS F625W + F775W images taken between June 1999 and December 2004 of several dozen debris fragments in the remnant's northeast ejecta stream and along the remnant's eastern limb reveal substantial emission variations ('flickering') over time scales as short as nine months. Such widespread and rapid variability indicates knot scale lengths ~ 10^15 cm and a highly inhomogeneous surrounding medium. We also identify a small percentage of ejecta knots located all around the remnant's outer periphery which show trailing emissions typically 0.2" to 0.7" in length aligned along the knot's direction of motion suggestive of knot ablation tails. We discuss the nature of these trailing emissions as they pertain to ablation cooling, knot disruption and fragmentation, and draw comparisons to the emission "strings" seen in eta Car. Finally, we identify several tight clusters of small ejecta knots which resemble models of shock induced fragmentation of larger SN ejecta knots caused by a high-velocity interaction with a lower density ambient medium.