# BSE versus StarTrack: implementations of new wind, remnant-formation,   and natal-kick schemes in NBODY7 and their astrophysical consequences

**Authors:** Sambaran Banerjee, Krzysztof Belczynski, Christopher L. Fryer, Peter, Berczik, Jarrod R. Hurley, Rainer Spurzem, Long Wang

arXiv: 1902.07718 · 2020-07-08

## TL;DR

This paper introduces new stellar-remnant formation and natal-kick schemes in NBODY7, demonstrating their astrophysical implications and consistency with population synthesis models, especially regarding black hole and neutron star masses and retention in clusters.

## Contribution

It develops and tests new implementations of wind, remnant formation, and natal-kick schemes in NBODY7, aligning results with StarTrack and exploring effects on black hole retention.

## Key findings

- New schemes produce NS and BH masses matching StarTrack.
- Different natal kicks influence BH retention in clusters.
- Primordial binary mergers affect BH mass distribution and spins.

## Abstract

The masses of stellar-remnant black holes (BH), as a result of their formation via massive single- and binary-stellar evolution, is of high interest in this era of gravitational-wave detection from binary black hole (BBH) and binary neutron star (BNS) mergers. Here we present new developments in the N-body evolution program NBODY7 in regards to its stellar-remnant formation and related schemes. We demonstrate that the newly-implemented stellar-wind and remnant-formation schemes in the NBODY7 code's BSE sector, such as the 'rapid' and the 'delayed' supernova (SN) schemes along with an implementation of pulsational-pair-instability and pair-instability supernova (PPSN/PSN), now produces neutron star (NS) and BH masses that agree nearly perfectly, over large ranges of zero-age-main sequence (ZAMS) mass and metallicity, with those from the StarTrack population-synthesis program. We also demonstrate the new implementations of various natal-kick mechanisms on NSs and BHs such as the 'convection-asymmetry-driven', 'collapse-asymmetry-driven', and 'neutrino-emission-driven' kicks, in addition to a fully consistent implementation of the standard, fallback-dependent, momentum-conserving natal kick. We find that the SN material fallback causes the convection-asymmetry kick to effectively retain similar number and mass of BHs in clusters as for the standard, momentum-conserving kick. The collapse-asymmetry kick would cause nearly all BHs to retain in clusters irrespective of remnant formation model and metallicity, whereas the inference of a large number of BHs in GCs would potentially rule out the neutrino-driven kick mechanism. Pre-SN mergers of massive primordial binaries would cause BH masses to deviate from the single-star ZAMS mass-remnant mass relation. Such mergers, at low metallicities, can produce low-spinning BHs within the PSN mass gap that can be retained in a stellar cluster.

## Full text

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## Figures

68 figures with captions in the complete paper: https://tomesphere.com/paper/1902.07718/full.md

## References

112 references — full list in the complete paper: https://tomesphere.com/paper/1902.07718/full.md

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Source: https://tomesphere.com/paper/1902.07718