A Classification Scheme for X-ray Bright Type Ia Supernova Remnants Based on Their Circumstellar Interaction

TL;DR

This paper investigates how different mass loss scenarios from Type Ia supernova progenitors influence their surrounding environments and the resulting supernova remnants, revealing diverse circumstellar interactions in observed remnants.

Contribution

It introduces a model grid exploring uniform isotropic outflows' effects on supernova remnants, linking progenitor mass loss characteristics to observable remnant properties.

Findings

Approximately 55% of young X-ray bright Type Ia SNRs show no significant circumstellar modification.

A small subset of SNRs expand into large cavities likely created by fast outflows.

Most SNRs expand into dense material, indicating slow progenitor outflows associated with accretion in younger populations.

Abstract

The parameter space for mass loss in Type Ia supernova progenitors is large, with different progenitor scenarios favoring different mass loss regimes. Here we focus on the impact that uniform and isotropic outflows have on the circumstellar environment of Type Ia supernova progenitors. We vary mass loss rate, wind velocity, and outflow duration, and evolve supernova remnant (SNR) models in this grid of circumstellar structures in order to compare the bulk properties of these models (ages, radii, and \feka\ centroids and luminosities) to observations. We find that roughly 55\% (7/13) of young X-ray bright Type Ia SNRs in the Milky Way and the Large Magellanic Cloud had progenitors that did not substantially modify their surroundings on $\sim$pc scales. This group includes SN Ia with a range of luminosities, and at least one likely product of a double detonation explosion in a sub-Chandrasekhar white dwarf. The other half of our sample can be divided in two distinct classes. A small subset of SNRs ($\sim$15\%, 2/13) have large radii and low \feka\ centroids and are likely expanding into large cavities that might have been excavated by fast ($\sim$1000 km/s), sustained progenitor outflows. The majority of the SNRs that are expanding into a modified medium ($\sim30\%$, 4/13) show evidence for dense material, likely associated with slow ($\sim$10 km/s) progenitor outflows, possibly a byproduct of accretion processes in near-Chandrasekhar white dwarfs spawned by younger stellar populations.