A VLT/FLAMES survey for massive binaries in Westerlund 1. IV. Wd1-5 - binary product and a pre-supernova companion for the magnetar CXOU J1647-45?

TL;DR

This study investigates the binary origin of a magnetar in Westerlund 1, providing evidence that binary interactions and mass transfer processes are crucial in magnetar formation, supported by detailed stellar analysis and evolutionary modeling.

Contribution

It presents the first detailed case study linking a specific magnetar to a disrupted binary system, highlighting the role of binary evolution in magnetar formation.

Findings

Wd1-5 shows chemical signatures of binary mass transfer.

The progenitor system likely involved a close binary with mass exchange.

The magnetar's progenitor was part of a disrupted binary system.

Abstract

The first soft gamma-ray repeater was discovered over three decades ago, and subsequently identified as a magnetar. However there is currently no consenus on the formation channel(s) of these objects. The presence of a magnetar in the starburst cluster Westerlund 1 implies a >40Msun progenitor, favouring formation in a binary that was disrupted at supernova. To test this hypothesis we searched for the putative pre-SN companion via a radial velocity survey to identify high-velocity runaways, with subsequent atmospheric analysis of the resultant candidate, Wd1-5. Wd1-5 appears overluminous for its spectroscopic mass and we find evidence of He- and N-enrichment, O-depletion, and critically C-enrichment, a combination of properties that is difficult to explain for a single star. We infer a pre-SN history for Wd1-5 which supposes an initial close binary comprising two stars of comparable (~41Msun+35Msun) masses. Efficient mass transfer from the initially more massive component leads to the mass-gainer evolving more rapidly, initiating luminous blue variable/common envelope evolution. Reverse, wind-driven mass transfer during its subsequent WC Wolf-Rayet phase leads to the carbon pollution of Wd1-5, before a type Ibc supernova disrupts the binary system. Under the assumption of a physical association between Wd1-5 and J1647-45, the secondary is identified as the magnetar progenitor; its common envelope evolutionary phase prevents spin-down of its core prior to SN and the seed magnetic field for the magnetar forms either in this phase or during the earlier episode of mass transfer in which it was spun-up. Our results suggest that binarity is a key ingredient in the formation of at least a subset of magnetars by preventing spin-down via core-coupling and potentially generating a seed magnetic field.