📝 SummarXiv

Abstract

The canonical formation of second-generation (G2) stars in globular clusters (GCs) from gas enriched and ejected by G1 (primordial) polluters faces substantial challenges, i.e. (i) a mass-budget problem and (ii) uncertainty in the source(s) of the abundance anomaly of light elements (AALE) in G2 stars. The merger of G1 low-mass main-sequence (MS) binaries can overcome (i), but its ability to result in AALE is omitted. We provide evidence of the merger process to explain AALE by relying on highly probable merger remnants in the Galactic disk. We focus on carbon-deficient red-clump giants with low mass of 1.0 M_{\sun} < M $\lesssim$ 2.0 M_{\sun} and hot He-intermediate subdwarfs of supersolar metallicity, both manifesting G2-like AALE incompatible with GC origin. The origin of such rare core He-burning stars as the mergers of [MS star (MSS)]+[helium white dwarf (HeWD)] binaries, evolved from low-mass high-mass ratio (MSS+MSS) ones, is supported by models evolving to either horizontal branch (HB) stars or He subdwarfs via the red giant branch (RGB). Such binaries in the GC NGC 362 contain very young ($\sim$ 4 Myr) extremely low-mass HeWDs, in contrast to much older ($\sim 100$ times) counterparts in open clusters. This agrees with the impact of GC environment on the lifetime of hard binaries: (MSS+HeWD) systems merge there soon after arising from (MSS+MSS) binaries that underwent the common-envelope stage of evolution. From the number and lifetime of the (MSS+HeWD) binaries uncovered in NGC 362, the expected fraction of their progeny RGB G2 stars is estimated to be $\lesssim$10\%. The field merger remnants with G2-like AALE support the merger nature of at least a fraction of G2 stars in GCs. The specific channel [(MSS+MSS) - (MSS+HeWD) - merger product] supported by observations and models is tentatively identified as the channel of formation of the extreme G2 RGB component in GCs.