Material mixing in pulsar wind nebulae of massive runaway stars

TL;DR

This study uses 2.5D MHD simulations to analyze how materials from pulsar winds, supernova ejecta, and stellar winds mix in nebulae around massive runaway stars, revealing the influence of stellar evolution and velocity on element distribution.

Contribution

It provides the first detailed simulation-based analysis of material mixing in pulsar wind nebulae considering different stellar progenitors and velocities.

Findings

Wolf Rayet materials mix up to 80% efficiently.

Supernova ejecta form complex patterns at higher velocities.

Pulsar wind mixing is more efficient in Wolf Rayet progenitors.

Abstract

In this study we quantitatively examine the manner pulsar wind, supernova ejecta and defunct stellar wind materials distribute and melt together into plerions. We performed 2.5D MHD simulations of the entire evolution of their stellar surroundings and different scenarios are explored, whether the star dies as a red supergiant and Wolf Rayet supernova progenitors, and whether it moved with velocity 20 km/s or 40 km/s through the ISM. Within the post explosion, early 10 kyr, the H burning products rich red supergiant wind only mixes by <= 20 per cent, due to its dense circumstellar medium filling the progenitor bow shock trail, still unaffected by the supernova blastwave. Wolf Rayet materials, enhanced in C, N, O elements, distribute circularly for the 35 Mo star moving at 20 km/s and oblongly at higher velocities, mixing efficiently up to 80 per cent. Supernova ejecta, filled with Mg, Si, Ca, Ti and Fe, remain spherical for longer times at 20 km/s but form complex patterns at higher progenitor speeds due to earlier interaction with the bow shock, in which they mix more efficiently. The pulsar wind mixing is more efficient for Wolf Rayet (25 per cent) than red supergiant progenitors (20 per cent). This work reveals that the past evolution of massive stars and their circumstellar environments critically shapes the internal distribution of chemical elements on plerionic supernova remnants, and, therefore, governs the origin of the various emission mechanisms at work therein. This is essential for interpreting multi-frequency observations of atomic and molecular spectral lines, such as in optical, infrared, and soft X rays.