# Signatures of hypermassive neutron star lifetimes on r-process   nucleosynthesis in the disk ejecta from neutron star mergers

**Authors:** Jonas Lippuner, Rodrigo Fern\'andez, Luke F. Roberts, Francois, Foucart, Daniel Kasen, Brian D. Metzger, Christian D. Ott

arXiv: 1703.06216 · 2017-09-26

## TL;DR

This study explores how the lifetime of hypermassive neutron stars influences the synthesis of heavy elements in neutron star merger ejecta, revealing key dependencies on neutrino irradiation and ejecta composition.

## Contribution

It introduces long-term axisymmetric hydrodynamic simulations of disk outflows from hypermassive neutron stars with variable lifetimes, incorporating detailed nucleosynthesis calculations.

## Key findings

- Short HMNS lifetimes produce abundances matching solar r-process patterns.
- Longer HMNS lifetimes underproduce lanthanides and actinides, requiring additional ejecta sources.
- Neutrino irradiation significantly affects mass ejection and nucleosynthesis outcomes.

## Abstract

We investigate the nucleosynthesis of heavy elements in the winds ejected by accretion disks formed in neutron star mergers. We compute the element formation in disk outflows from hypermassive neutron star (HMNS) remnants of variable lifetime, including the effect of angular momentum transport in the disk evolution. We employ long-term axisymmetric hydrodynamic disk simulations to model the ejecta, and compute r-process nucleosynthesis with tracer particles using a nuclear reaction network containing $\sim 8000$ species. We find that the previously known strong correlation between HMNS lifetime, ejected mass, and average electron fraction in the outflow is directly related to the amount of neutrino irradiation on the disk, which dominates mass ejection at early times in the form of a neutrino-driven wind. Production of lanthanides and actinides saturates at short HMNS lifetimes ($\lesssim 10$ ms), with additional ejecta contributing to a blue optical kilonova component for longer-lived HMNSs. We find good agreement between the abundances from the disk outflow alone and the solar r-process distribution only for short HMNS lifetimes ($\lesssim 10$ ms). For longer lifetimes, the rare-earth and third r-process peaks are significantly under-produced compared to the solar pattern, requiring additional contributions from the dynamical ejecta. The nucleosynthesis signature from a spinning black hole (BH) can only overlap with that from a HMNS of moderate lifetime ($\lesssim 60$ ms). Finally, we show that angular momentum transport not only contributes with a late-time outflow component, but that it also enhances the neutrino-driven component by moving material to shallower regions of the gravitational potential, in addition to providing additional heating.

## Full text

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## Figures

11 figures with captions in the complete paper: https://tomesphere.com/paper/1703.06216/full.md

## References

99 references — full list in the complete paper: https://tomesphere.com/paper/1703.06216/full.md

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Source: https://tomesphere.com/paper/1703.06216