Late-time Evolution of Composite Supernova Remnants: Deep Chandra Observations and Hydrodynamical Modeling of a Crushed Pulsar Wind Nebula in SNR G327.1-1.1

TL;DR

This study combines deep X-ray observations and hydrodynamical modeling to analyze the complex late-time evolution of a composite supernova remnant and its pulsar wind nebula, revealing asymmetric interactions with the reverse shock.

Contribution

It provides new insights into the morphology and evolution of composite SNRs through detailed observations and simulations of SNR G327.1-1.1, highlighting the effects of ambient density gradients and pulsar motion.

Findings

PWN shows a bow shock-like structure and arcs indicating asymmetric interaction.

Hydrodynamical models suggest a ~17,000-year-old SNR expanding into a density gradient.

The PWN's broadband spectrum can be explained by RS/PWN interaction scenarios.

Abstract

In an effort to better understand the evolution of composite supernova remnants (SNRs) and the eventual fate of relativistic particles injected by their pulsars, we present a multifaceted investigation of the interaction between a pulsar wind nebula (PWN) and its host SNR G327.1-1.1. Our 350 ks Chandra X-ray observations of SNR G327.1-1.1 reveal a highly complex morphology; a cometary structure resembling a bow shock, prong-like features extending into large arcs in the SNR interior, and thermal emission from the SNR shell. Spectral analysis of the non-thermal emission offers clues about the origin of the PWN structures, while enhanced abundances in the PWN region provide evidence for mixing of supernova ejecta with PWN material. The overall morphology and spectral properties of the SNR suggest that the PWN has undergone an asymmetric interaction with the SNR reverse shock (RS) that can occur as a result of a density gradient in the ambient medium and/or a moving pulsar that displaces the PWN from the center of the remnant. We present hydrodynamical simulations of G327.1-1.1 that show that its morphology and evolution can be described by a ~ 17,000 yr old composite SNR that expanded into a density gradient with an orientation perpendicular to the pulsar's motion. We also show that the RS/PWN interaction scenario can reproduce the broadband spectrum of the PWN from radio to gamma-ray wavelengths. The analysis and modeling presented in this work have important implications for our general understanding of the structure and evolution of composite SNRs.