The forward and reverse shock dynamics of Cassiopeia A

TL;DR

This study measures the proper motions of Cassiopeia A's shocks over 19 years, revealing complex acceleration patterns and providing insights into the remnant's interaction with its environment and jet dynamics.

Contribution

It presents the first detailed proper motion analysis of both forward and reverse shocks in Cassiopeia A, including acceleration measurements and implications for the remnant's environment.

Findings

Forward shock expands at ~5800 km/s with deceleration in the east.

Reverse shock moves outward in the east but inward in the west, with velocities up to 8000 km/s.

Proper motions of the northeastern jet indicate velocities of 7830-9200 km/s.

Abstract

We report on proper motion measurements of the forward- and reverse-shock regions of the supernova remnant Cassiopeia A (Cas A), including deceleration/acceleration measurements of the forward shock. The measurements combine 19 years of observations with the Chandra X-ray Observatory, using the 4.2-6 keV continuum band, preferentially targeting X-ray synchrotron radiation. The average expansion rate is $0.218 \pm 0.029$%yr$^{-1}$ for the forward shock, corresponding to a velocity of $\approx 5800$ km/s. The time derivative of the proper motions indicates deceleration in the east, and an acceleration up to $1.1\times 10^{-4}$ yr$^{-2}$ in the western part. The reverse shock moves outward in the East, but in the West it moves toward the center with an expansion rate of $-0.0225\pm 0.0007$ %yr$^{-1}$, corresponding to $-1884\pm 17$ km/s. In the West the reverse shock velocity in the ejecta frame is $\gtrsim 3000$ km/s, peaking at $\sim 8000$ km/s, explaining the presence of X-ray synchrotron emitting filaments there. The backward motion of the reverse shock can be explained by either a scenario in which the forward shock encountered a partial, dense, wind shell, or one in which the shock transgressed initially through a lopsided cavity, created during a brief Wolf-Rayet star phase. Both scenarios are consistent with the local acceleration of the forward shock. Finally we report on the proper motion of the northeastern jet, using both the X-ray continuum band, and the Si XIII K-line emission band. We find expansion rates of respectively 0.21%yr$^{-1}$ and 0.24%yr$^{-1}$, corresponding to velocities at the tip of the X-ray jet of 7830--9200 km/s.