Probing the Incompressibility of Nuclear Matter at Ultrahigh Density through the Prompt Collapse of Asymmetric Neutron Star Binaries

Albino Perego; Domenico Logoteta; David Radice; Sebastiano Bernuzzi; Rahul Kashyap; Abhishek Das; Surendra Padamata; Aviral Prakash

doi:10.1103/PhysRevLett.129.032701

Probing the Incompressibility of Nuclear Matter at Ultrahigh Density through the Prompt Collapse of Asymmetric Neutron Star Binaries

Albino Perego, Domenico Logoteta, David Radice, Sebastiano Bernuzzi, Rahul Kashyap, Abhishek Das, Surendra Padamata, Aviral Prakash

Physics

Research output: Contribution to journal › Article › peer-review

35 Scopus citations

Abstract

Using 250 neutron star merger simulations with microphysics, we explore for the first time the role of nuclear incompressibility in the prompt collapse threshold for binaries with different mass ratios. We demonstrate that observations of prompt collapse thresholds, either from binaries with two different mass ratios or with one mass ratio but combined with the knowledge of the maximum neutron star mass or compactness, will constrain the incompressibility at the maximum neutron star density Kmax to within tens of percent. This otherwise inaccessible measure of Kmax can potentially reveal the presence of hyperons or quarks inside neutron stars.

Original language	English (US)
Article number	032701
Journal	Physical review letters
Volume	129
Issue number	3
DOIs	https://doi.org/10.1103/PhysRevLett.129.032701
State	Published - Jul 15 2022

All Science Journal Classification (ASJC) codes

General Physics and Astronomy

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10.1103/PhysRevLett.129.032701

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abstract = "Using 250 neutron star merger simulations with microphysics, we explore for the first time the role of nuclear incompressibility in the prompt collapse threshold for binaries with different mass ratios. We demonstrate that observations of prompt collapse thresholds, either from binaries with two different mass ratios or with one mass ratio but combined with the knowledge of the maximum neutron star mass or compactness, will constrain the incompressibility at the maximum neutron star density Kmax to within tens of percent. This otherwise inaccessible measure of Kmax can potentially reveal the presence of hyperons or quarks inside neutron stars.",

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AU - Perego, Albino

AU - Logoteta, Domenico

AU - Radice, David

AU - Bernuzzi, Sebastiano

AU - Kashyap, Rahul

AU - Das, Abhishek

AU - Padamata, Surendra

AU - Prakash, Aviral

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AB - Using 250 neutron star merger simulations with microphysics, we explore for the first time the role of nuclear incompressibility in the prompt collapse threshold for binaries with different mass ratios. We demonstrate that observations of prompt collapse thresholds, either from binaries with two different mass ratios or with one mass ratio but combined with the knowledge of the maximum neutron star mass or compactness, will constrain the incompressibility at the maximum neutron star density Kmax to within tens of percent. This otherwise inaccessible measure of Kmax can potentially reveal the presence of hyperons or quarks inside neutron stars.

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Probing the Incompressibility of Nuclear Matter at Ultrahigh Density through the Prompt Collapse of Asymmetric Neutron Star Binaries

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