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Preparing the next gravitational million-body simulations: evolution of single and binary stars in <tt> <scp>nbody6++gpu</scp> </tt>, <tt> <scp>mocca</scp> </tt>, and <tt> <scp>mcluster</scp> </tt>

Albrecht Kamlah, Agostino Leveque, Rainer Spurzem, M Arca Sedda, Abbas Askar, Sambaran Banerjee, Peter Berczik, Mirek Giersz, Jarrod R. Hurley, Diogo Belloni, L. Kühmichel, Long Wang

2021Monthly Notices of the Royal Astronomical Society67 citationsDOI

Abstract

ABSTRACT We present the implementation of updated stellar evolution recipes in the codes nbody6++gpu, mocca, and mcluster. We test them through numerical simulations of star clusters containing 1.1 × 105 stars (with 2.0 × 104 in primordial hard binaries) performing high-resolution direct N-body (nbody6++gpu) and Monte Carlo (mocca) simulations to an age of 10 Gyr. We compare models implementing either delayed or core-collapse supernovae mechanisms, a different mass ratio distribution for binaries, and white dwarf (WD) natal kicks enabled/disabled. Compared to nbody6++gpu, the mocca models appear to be denser, with a larger scatter in the remnant masses, and a lower binary fraction on average. The mocca models produce more black holes (BHs) and helium WDs, while nbody6++gpu models are characterized by a much larger amount of WD–WD binaries. The remnant kick velocity and escape speed distributions are similar for the BHs and neutron stars (NSs), and some NSs formed via electron-capture supernovae, accretion-induced collapse, or merger-induced collapse escape the cluster in all simulations. The escape speed distributions for the WDs, on the other hand, are very dissimilar. We categorize the stellar evolution recipes available in nbody6++gpu into four levels: the one implemented in previous nbody6++gpu and mocca versions (level A), state-of-the-art prescriptions (level B), some in a testing phase (level C), and those that will be added in future versions of our codes.

Topics & Concepts

PhysicsSupernovaStarsAstrophysicsWhite dwarfBlack hole (networking)PleiadesBinary numberStar clusterComputer scienceLink-state routing protocolRouting protocolComputer networkArithmeticRouting (electronic design automation)MathematicsPulsars and Gravitational Waves ResearchStellar, planetary, and galactic studiesGamma-ray bursts and supernovae
Preparing the next gravitational million-body simulations: evolution of single and binary stars in <tt> <scp>nbody6++gpu</scp> </tt>, <tt> <scp>mocca</scp> </tt>, and <tt> <scp>mcluster</scp> </tt> | Litcius