%AGünther, Hans%AHoadley, Keri%AGünther, Maximilian%AMetzger, Brian%ASchneider, P.%AShen, Ken%BJournal Name: The Astronomical Journal; Journal Volume: 163; Journal Issue: 4; Related Information: CHORUS Timestamp: 2024-01-09 12:33:18 %D2022%IDOI PREFIX: 10.3847 %JJournal Name: The Astronomical Journal; Journal Volume: 163; Journal Issue: 4; Related Information: CHORUS Timestamp: 2024-01-09 12:33:18 %K %MOSTI ID: 10364017 %PMedium: X; Size: Article No. 173 %TX-Ray Emission from Candidate Stellar Merger Remnant TYC 2597-735-1 and Its Blue Ring Nebula %XAbstract

Tight binary or multiple-star systems can interact through mass transfer and follow vastly different evolutionary pathways than single stars. The star TYC 2597-735-1 is a candidate for a recent stellar merger remnant resulting from a coalescence of a low-mass companion with a primary star a few thousand years ago. This violent event is evident in a conical outflow (“Blue Ring Nebula”) emitting in UV light and surrounded by leading shock filaments observed in Hαand UV emission. From Chandra data, we report the detection of X-ray emission from the location of TYC 2597-735-1 with a luminositylog(LX/Lbol)=5.5. Together with a previously reported period of ~14 days, this indicates ongoing stellar activity and the presence of strong magnetic fields on TYC 2597-735-1. Supported by stellar evolution models of merger remnants, we interpret the inferred stellar magnetic field as dynamo action associated with a newly formed convection zone in the atmosphere of TYC 2597-735-1, though internal shocks at the base of an accretion-powered jet cannot be ruled out. We speculate that this object will evolve into an FK Com–type source, i.e., a class of rapidly spinning magnetically active stars for which a merger origin has been proposed but for which no relic accretion or large-scale nebula remains visible. We also detect likely X-ray emission from two small regions close to the outer shock fronts in the Blue Ring Nebula, which may arise from inhomogeneities either in the circumstellar medium or in the mass and velocity distribution in the merger-driven outflow.

%0Journal Article