Light element variations in globular clusters via nucleosynthesis in black hole accretion discs

Abstract

Ancient globular clusters contain multiple stellar populations identified by variations in light elements (e.g., C, N, O, Na). Although many scenarios have been suggested to explain this phenomenon, all are faced with challenges when compared with all the observational evidence. In this Letter, we propose a new scenario in which light element variations originate from nucleosynthesis in accretion discs around black holes. Since the black holes form after a few Myrs, the cluster is expected to still be embedded in a gas rich environment. Through a simplified accretion model, we show that the correct light element anti-correlations can be produced. Assuming a Kroupa stellar initial mass function (IMF), each black hole would only have to process ≈300M of material in order to explain multiple populations; over a period of 3Myr this corresponds to 10-4 Myr-1 (similar to the estimated accretion rate for the X-ray binary SS 433).