Investigating black hole accretion disks as potential polluter sources for the formation of enriched stars in globular clusters

Autor(en)

Laurane Fréour, Alice Zocchi, Glenn van de Ven, Elena Pancino

Abstrakt

Accretion disks surrounding stellar mass black holes have been suggested as potential locations for the nucleosynthesis of light elements, which are our primary observational discriminant of multiple stellar populations within globular clusters. The population of enriched stars in globular clusters are enhanced in

¹⁴N,

²³Na, and sometimes in

²⁷Al and/or in

³⁹K. In this study, our aim is to investigate the feasibility of initiating nucleosynthesis for these four elements in black hole accretion disks, considering various internal parameters such as the temperature of the gas and timescale of the accretion. To achieve this, we employed a 132-species reaction network. We used the slim disk model, suitable for the Super-Eddington mass accretion rate and for geometrically and optically thick disks. We explored the conditions related to the mass, mass accretion rate, viscosity, and radius of the black hole-accretion disk system that would allow for the creation of

¹⁴N,

²³Na,

²⁷Al, and

³⁹K before the gas is accreted onto the central object. This happens when the nucleosynthesis timescale is shorter than the viscous timescale. Our findings reveal that there is no region in the parameter space where the formation of

²³Na can occur and only a very limited region where the formation of

¹⁴N,

²⁷Al, and

³⁹K is plausible. Specifically, this occurs for black holes with masses lower than 10 solar masses (m<10 M

_⊙), with a preference toward even lower mass values (m<1 M

_⊙) and extremely low viscosity parameters (α<10

^-3). Such values are highly unlikely based on current observations of stellar mass black holes. However, such low mass black holes could actually exist in the early universe, as so-called primordial black holes. In conclusion, our study suggests that the nucleosynthesis within black hole accretion disks of elements of interest for the multiple stellar populations, namely,

¹⁴N,

²³Na,

²⁷Al, and

³⁹K is improbable, but not impossible, using the slim disk model. Future gravitational wave missions will help constrain the existence of tiny and light black holes.

Organisation(en)

Institut für Astrophysik

Externe Organisation(en)

INAF - Osservatorio Astrofisico di Arcetri

Journal

Astronomy & Astrophysics

Band

684

Anzahl der Seiten

11

ISSN

0004-6361

DOI

https://doi.org/10.1051/0004-6361/202348036

Publikationsdatum

04-2024

Peer-reviewed

Ja

ÖFOS 2012

103003 Astronomie, 103004 Astrophysik

Schlagwörter

ASJC Scopus Sachgebiete

Astronomy and Astrophysics, Space and Planetary Science

Link zum Portal

https://ucrisportal.univie.ac.at/de/publications/e84330a7-1b86-4509-a451-fa5cbcbd8268