Equation of state constraints from neutron stars

James M. Lattimer

doi:10.1007/978-1-4020-5998-8_46

Equation of state constraints from neutron stars

James M. Lattimer

Physics and Astronomy

Research output: Chapter in Book/Report/Conference proceeding › Chapter › peer-review

Abstract

Recent measurements of thermal radiation from neutron stars have suggested a rather broad range of radiation radii (). Sources in M13 and Omega Cen imply R _∞∼12-14 km, but X7 in 47 Tuc implies R _∞∼16-20 km and RX J1856-3754 R _∞>17 km. If these measurements are all correct, only a limited selection of EOS's could be consistent with them, but a broad range of neutron star masses (up to 2 M) would also be necessary. The surviving equations of state are incompatible with significant softening above nuclear saturation densities, such as would occur with Boson condensates, a low-density quark-hadron transition, or hyperons. Other potential constraints, such as from QPO's, radio pulsar mass and moment of inertia measurements, and neutron star cooling, are compared.

Original language	English
Title of host publication	Isolated Neutron Stars
Subtitle of host publication	From The Surface To The Interior
Publisher	Springer Netherlands
Pages	371-379
Number of pages	9
ISBN (Print)	9781402059971
DOIs	https://doi.org/10.1007/978-1-4020-5998-8_46
State	Published - 2007

Keywords

Equation of state
Neutron stars
Pulsars

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10.1007/978-1-4020-5998-8_46

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title = "Equation of state constraints from neutron stars",

abstract = "Recent measurements of thermal radiation from neutron stars have suggested a rather broad range of radiation radii (). Sources in M13 and Omega Cen imply R ∞∼12-14 km, but X7 in 47 Tuc implies R ∞∼16-20 km and RX J1856-3754 R ∞>17 km. If these measurements are all correct, only a limited selection of EOS's could be consistent with them, but a broad range of neutron star masses (up to 2 M) would also be necessary. The surviving equations of state are incompatible with significant softening above nuclear saturation densities, such as would occur with Boson condensates, a low-density quark-hadron transition, or hyperons. Other potential constraints, such as from QPO's, radio pulsar mass and moment of inertia measurements, and neutron star cooling, are compared.",

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AB - Recent measurements of thermal radiation from neutron stars have suggested a rather broad range of radiation radii (). Sources in M13 and Omega Cen imply R ∞∼12-14 km, but X7 in 47 Tuc implies R ∞∼16-20 km and RX J1856-3754 R ∞>17 km. If these measurements are all correct, only a limited selection of EOS's could be consistent with them, but a broad range of neutron star masses (up to 2 M) would also be necessary. The surviving equations of state are incompatible with significant softening above nuclear saturation densities, such as would occur with Boson condensates, a low-density quark-hadron transition, or hyperons. Other potential constraints, such as from QPO's, radio pulsar mass and moment of inertia measurements, and neutron star cooling, are compared.

KW - Equation of state

KW - Neutron stars

KW - Pulsars

UR - https://www.scopus.com/pages/publications/84892837178

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DO - 10.1007/978-1-4020-5998-8_46

M3 - Chapter

AN - SCOPUS:84892837178

SN - 9781402059971

SP - 371

EP - 379

BT - Isolated Neutron Stars

PB - Springer Netherlands

ER -

Equation of state constraints from neutron stars

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Keywords

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