Saved in:
Bibliographic Details
Main Authors: Rivieccio, Giuseppe, Nadal-Matosas, Adriana, Rios, Arnau, Ruiz, Milton
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2501.16795
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866912491861180416
author Rivieccio, Giuseppe
Nadal-Matosas, Adriana
Rios, Arnau
Ruiz, Milton
author_facet Rivieccio, Giuseppe
Nadal-Matosas, Adriana
Rios, Arnau
Ruiz, Milton
contents Motivated by gravitational wave observations of binary neutron-star mergers, we study the thermal index of low-density, high-temperature dense matter. We use the virial expansion to account for nuclear interaction effects. We focus on the region of validity of the expansion, which reaches $10^{-3}$ fm$^{-3}$ at $T=5$ MeV up to almost saturation density at $T=50$ MeV. In pure neutron matter, we find an analytical expression for the thermal index, and show that it is nearly density- and temperature-independent, within a fraction of a percent of the non-interacting, non-relativistic value of $Γ_\text{th} \approx 5/3$. When we incorporate protons, electrons and photons, we find that the density and temperature dependence of the thermal index changes significantly. We predict a smooth transition between an electron-dominated regime with $Γ_\text{th} \approx 4/3$ at low densities to a neutron-dominated region with $Γ_\text{th} \approx 5/3$ at high densities. This behavior is by and large independent of proton fraction and is not affected by nuclear interactions in the region where the virial expansion converges. We model this smooth transition analytically and provide a simple but accurate parametrization of the inflection point between these regimes. When compared to tabulated realistic models of the thermal index, we find an overall agreement at high temperatures that weakens for colder matter. The discrepancies can be attributed to the missing contributions of nuclear clusters. The virial approximation provides a clear and physically intuitive framework for understanding the thermal properties of dense matter, offering a computationally efficient solution that makes it particularly well-suited for the regimes relevant to neutron star binary remnants.
format Preprint
id arxiv_https___arxiv_org_abs_2501_16795
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle The thermal index of neutron-star matter in the virial approximation
Rivieccio, Giuseppe
Nadal-Matosas, Adriana
Rios, Arnau
Ruiz, Milton
Nuclear Theory
High Energy Astrophysical Phenomena
General Relativity and Quantum Cosmology
Motivated by gravitational wave observations of binary neutron-star mergers, we study the thermal index of low-density, high-temperature dense matter. We use the virial expansion to account for nuclear interaction effects. We focus on the region of validity of the expansion, which reaches $10^{-3}$ fm$^{-3}$ at $T=5$ MeV up to almost saturation density at $T=50$ MeV. In pure neutron matter, we find an analytical expression for the thermal index, and show that it is nearly density- and temperature-independent, within a fraction of a percent of the non-interacting, non-relativistic value of $Γ_\text{th} \approx 5/3$. When we incorporate protons, electrons and photons, we find that the density and temperature dependence of the thermal index changes significantly. We predict a smooth transition between an electron-dominated regime with $Γ_\text{th} \approx 4/3$ at low densities to a neutron-dominated region with $Γ_\text{th} \approx 5/3$ at high densities. This behavior is by and large independent of proton fraction and is not affected by nuclear interactions in the region where the virial expansion converges. We model this smooth transition analytically and provide a simple but accurate parametrization of the inflection point between these regimes. When compared to tabulated realistic models of the thermal index, we find an overall agreement at high temperatures that weakens for colder matter. The discrepancies can be attributed to the missing contributions of nuclear clusters. The virial approximation provides a clear and physically intuitive framework for understanding the thermal properties of dense matter, offering a computationally efficient solution that makes it particularly well-suited for the regimes relevant to neutron star binary remnants.
title The thermal index of neutron-star matter in the virial approximation
topic Nuclear Theory
High Energy Astrophysical Phenomena
General Relativity and Quantum Cosmology
url https://arxiv.org/abs/2501.16795