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High angular momentum hot differentially rotating equilibrium star evolutions in conformally flat spacetime

High Energy Astrophysical Phenomena 2024-08-12 v3 General Relativity and Quantum Cosmology

Abstract

The conformal flatness approximation to the Einstein equations has been successfully used in many astrophysical applications such as initial data constructions and dynamical simulations. Although it has been shown that full general relativistic strongly differentially rotating equilibrium models deviate by at most a few percent from their conformally flat counterparts, whether those conformally flat solutions remain stable has not been fully addressed. To further understand the limitations of the conformal flatness approximation, in this work, we construct spatially-conformally-flat hot hypermassive neutron stars with post-merger-like rotation laws, and perform conformally flat evolutions and analysis over dynamical timescales. We find that enforcing conformally-flat spacetime could change the equilibrium of quasi-toroidal models with high angular momentum for J9 GM2/cJ \gtrsim 9 ~G M_{\odot}^2 / c compared to fully general relativistic cases. In contrast, all the quasi-spherical models considered in this work remain stable even with high angular momentum J=9 GM2/cJ=9~G M_{\odot}^2 / c. Our investigation suggests that the quasi-spherical models are suitable initial data for long-lived hypermassive neutron star modeling in conformally flat spacetime.

Keywords

Cite

@article{arxiv.2402.18529,
  title  = {High angular momentum hot differentially rotating equilibrium star evolutions in conformally flat spacetime},
  author = {Patrick Chi-Kit Cheong and Nishad Muhammed and Pavan Chawhan and Matthew D. Duez and Francois Foucart and Lawrence E. Kidder and Harald P. Pfeiffer and Mark A. Scheel},
  journal= {arXiv preprint arXiv:2402.18529},
  year   = {2024}
}
R2 v1 2026-06-28T15:03:34.912Z