Asteroseismic predictions for a massive main-sequence merger product (2504.08683v1)

Abstract: The products of stellar mergers between two massive main-sequence (MS) stars appear as seemingly normal MS stars after a phase of thermal relaxation, if not for certain peculiarities. Since these peculiarities are not limited to the merger product's surface, we use asteroseismology to predict how the differences in the internal structure of a merger product and a genuine single star manifest via properties of non-radial stellar pulsations. We mapped the result of a 3D MHD stellar merger simulation between a 9 and an 8 solar-mass MS star to 1D and evolved it through the MS. We compare the predicted pressure (p) and gravity (g) modes for the merger product model with those predicted for a corresponding genuine single-star model. The p-mode frequencies are consistently lower for the merger product than for the genuine single star, and the differences between them are more than a thousand times larger than the current best observational uncertainties for measured mode frequencies of this kind. Even though g-mode period spacing differences vary in value and sign throughout the MS, they, too, are larger than the current best observational uncertainties for such long-period modes. This, combined with additional variability in the merger product's period spacing patterns, shows the potential of identifying merger products in future-forward modelling. We also attempt to replicate the merger product's structure using three widely applied 1D merger prescriptions and repeat the asteroseismic analysis. Although none of the 1D prescriptions reproduces the entire merger product's structure, we conclude that the prescription with shock heating shows the highest potential, provided that it can be calibrated on binary-evolution-driven 3D merger simulations. Our work should be expanded to encompass the various possible merger product structures predicted to exist in the Universe. (abridged)