Hard X-ray emissions from Cassiopeia A observed by INTEGRAL

TL;DR

This study analyzes ten years of INTEGRAL data to detect and characterize high-energy X-ray emissions from Cassiopeia A, revealing non-thermal radiation up to 220 keV and providing insights into supernova explosion asymmetries.

Contribution

First detection of non-thermal continuum emission from Cas A up to 220 keV using INTEGRAL data, and analysis of its origin related to asymmetric supernova explosion scenarios.

Findings

Detected $^{44}$Ti line emissions confirming previous measurements.

Non-thermal emission fits a power-law model without cutoff up to 220 keV.

Inconsistent with diffusive shock acceleration models at low shock velocities.

Abstract

Cassiopeia A (Cas A) as the nearby young remnant of a core-collapse supernova is the best candidate for astrophysical studies in supernova explosion and its environment. We studied hard X-ray emissions from Cas A using the ten-year data of INTEGRAL observations, and first detected non-thermal continuum emission from the source up to 220 keV. The $^{44}$Ti line emissions at 68 and 78 keV are confirmed by our observations with a mean flux of $\sim (2.2\pm 0.4)\times 10^{-5}$ ph cm$^{-2}$ s$^{-1}$, corresponding to a $^{44}$Ti yield in Cas A of $(1.3\pm 0.4)\times 10^{-4}$ \ms. The continuum emission from 3 -- 500 keV can be fitted with a thermal bremsstrahlung of $kT\sim 0.79\pm 0.08$ keV plus a power-law model of $\Gamma \sim 3.13\pm 0.03$. The non-thermal emission from Cas A is well fitted with a power-law model without a cutoff up to 220 keV. This radiation characteristic is inconsistent with the diffusive shock acceleration models with the remnant shock velocity of only 5000km s$^{-1}$. The central compact object in Cas A cannot contribute to the emission above 80 keV significantly. Some possible physical origins of the non-thermal emission above 80 keV from the remnant shock are discussed. We deduce that the asymmetrical supernova explosion scenario of Cas A is a promising scenario to produce high energy synchrotron radiation photons, where a part of ejecta with the velocity of $\sim 0.1c$ and opening angle of $\sim10^\circ$ can account for the 100-keV emission, consistent with the "jet" observed in Cas A.