Near-infrared Extinction due to Cool Supernova Dust in Cassiopeia A

TL;DR

This study measures and analyzes near-infrared extinction caused by supernova dust in Cassiopeia A, revealing the presence of warm and cool dust components with distinct compositions and sizes, indicating different dust formation environments.

Contribution

It provides the first detailed correlation between NIR extinction and ejecta velocity in Cassiopeia A, identifying multiple dust components and their properties within the supernova remnant.

Findings

Detection of internal self-extinction indicating large SN dust mass

Identification of warm silicate and cool Fe or Si dust components

Evidence for dust formation in both diffuse ejecta and dense clumps

Abstract

We present the results of extinction measurements toward the main ejecta shell of the Cassiopeia A supernova (SN) remnant using the flux ratios between the two near-infrared (NIR) [Fe II] lines at 1.26 and 1.64 $\mu {\rm m}$. We find a clear correlation between the NIR extinction ($E(J-H)$) and the radial velocity of ejecta knots, showing that redshifted knots are systematically more obscured than blueshifted ones. This internal "self-extinction" strongly indicates that a large amount of SN dust resides inside and around the main ejecta shell. At one location in the southern part of the shell, we measure $E(J-H)$ by the SN dust of 0.23$\pm$0.05 mag. By analyzing the spectral energy distribution of thermal dust emission at that location, we show that there are warm ($\sim$100 K) and cool ($\sim$40 K) SN dust components and that the latter is responsible for the observed $E(J-H)$. We investigate the possible grain species and size of each component and find that the warm SN dust needs to be silicate grains such as MgSiO$_{3}$, Mg$_{2}$SiO$_{4}$, and SiO$_{2}$, whereas the cool dust could be either small ($\leq$0.01 $\mu {\rm m}$) Fe or large ($\geq$0.1 $\mu {\rm m}$) Si grains. We suggest that the warm and cool dust components in Cassiopeia A represent grain species produced in diffuse SN ejecta and in dense ejecta clumps, respectively.