The Demographics of Binary Companions to Stripped-Envelope Supernovae: Confronting Observations with Population Synthesis

TL;DR

This study compares observed binary companions of stripped-envelope supernovae with population synthesis models, revealing insights into their demographics, progenitor systems, and the role of binary interactions in supernova evolution.

Contribution

It provides the first statistical comparison between observed companion data and binary population-synthesis predictions for SESNe, using new models from the POSYDON framework.

Findings

Companion detection fraction broadly matches model predictions.

Most undetected companions are likely faint or undetectable.

Current data disfavor efficient mass accretion in progenitor systems.

Abstract

Stripped-envelope supernovae (SESNe) mark the deaths of massive stars without hydrogen-rich envelopes. Most SESNe likely originate from binary systems where a companion stripped the progenitor of its envelope. Years of HST imaging of nearby SESNe sites have produced a statistically meaningful sample of constraints on surviving binary companions. We assemble the current sample of six companion detections and six non-detections from the literature, re-analyzing whenever needed. We then conduct the first statistical comparison with binary population-synthesis predictions, primarily based on new calculations performed with the POSYDON framework. Across a metallicity range, our models predict that 80-90% of Type Ib/c and 60-85% of IIb SNe explode with a rapidly rotating, main-sequence companion. The observed luminosity distribution favors fairly inefficient mass accretion and failed explosions of the most massive stripped stars. The companion detection fraction broadly matches predictions, given the imaging depth, but appears elevated for Type IIb SNe. In all but one non-detection, a faint, undetected companion is the most likely scenario. The red, apparently evolved companions in a few Type Ib/c SNe may result from strong interaction with the ejecta, expected in $\sim$12% of them. Companion demographics offer a powerful, independent probe of SESN progenitor systems, with the current sample disfavoring efficient accretion and supporting Wolf-Rayet non-explodability. Larger companion samples and follow-up studies will further clarify binary pathways to SESNe, serving as benchmarks for transient surveys.