Stable quark stars beyond neutron stars: Can they account for the missing matter ?

Sonja Kabana; Peter Minkowski

doi:10.22323/1.007.0203

Stable quark stars beyond neutron stars: Can they account for the missing matter ?

Sonja Kabana
, Peter Minkowski

University of Bern

Producción científica: Contribución a una revista › Artículo de la conferencia › revisión exhaustiva

Resumen

The structure of a spherically symmetric stable dark'star' is discussed, at zero temperature, containing 1) a core of quarks in the deconfined phase and antileptons 2) a shell of hadrons in particular n, p, ? and S- and leptons or antileptons and 3) a shell of hydrogen in the superfluid phase. If the superfluid hydrogen phase goes over into the electromagnetic plasma phase at densities well below one atom / (10 fm)³, as is usually assumed, the hydrogen shell is insignificant for the mass and the radius of the'star'. These quantities are then determined approximatively: mass = 1.8 solar masses and radius = 9.2 km. On the contrary if densities of the order of one atom / (10 fm)³ do form a stable hydrogen superfluid phase, we find a large range of possible masses from 1.8 to 375 solar masses. The radii vary accordingly from 9 to 1200 km.

Idioma original	Inglés
Publicación	Proceedings of Science
Volumen	7
DOI	https://doi.org/10.22323/1.007.0203
Estado	Publicada - 2001
Publicado de forma externa	Sí
Evento	2001 International Europhysics Conference on High Energy Physics, HEP 2001 - Budapest, Hungría Duración: 12 jul. 2001 → 18 jul. 2001

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title = "Stable quark stars beyond neutron stars: Can they account for the missing matter ?",

abstract = "The structure of a spherically symmetric stable dark'star' is discussed, at zero temperature, containing 1) a core of quarks in the deconfined phase and antileptons 2) a shell of hadrons in particular n, p, ? and S- and leptons or antileptons and 3) a shell of hydrogen in the superfluid phase. If the superfluid hydrogen phase goes over into the electromagnetic plasma phase at densities well below one atom / (10 fm)3, as is usually assumed, the hydrogen shell is insignificant for the mass and the radius of the'star'. These quantities are then determined approximatively: mass = 1.8 solar masses and radius = 9.2 km. On the contrary if densities of the order of one atom / (10 fm)3 do form a stable hydrogen superfluid phase, we find a large range of possible masses from 1.8 to 375 solar masses. The radii vary accordingly from 9 to 1200 km.",

keywords = "Dark matter, Quark stars",

author = "Sonja Kabana and Peter Minkowski",

note = "Publisher Copyright: {\textcopyright} Proceedings of Science 2001. All rights reserved.; 2001 International Europhysics Conference on High Energy Physics, HEP 2001 ; Conference date: 12-07-2001 Through 18-07-2001",

year = "2001",

doi = "10.22323/1.007.0203",

language = "English",

volume = "7",

journal = "Proceedings of Science",

issn = "1824-8039",

}

TY - JOUR

T1 - Stable quark stars beyond neutron stars

T2 - 2001 International Europhysics Conference on High Energy Physics, HEP 2001

AU - Kabana, Sonja

AU - Minkowski, Peter

PY - 2001

Y1 - 2001

N2 - The structure of a spherically symmetric stable dark'star' is discussed, at zero temperature, containing 1) a core of quarks in the deconfined phase and antileptons 2) a shell of hadrons in particular n, p, ? and S- and leptons or antileptons and 3) a shell of hydrogen in the superfluid phase. If the superfluid hydrogen phase goes over into the electromagnetic plasma phase at densities well below one atom / (10 fm)3, as is usually assumed, the hydrogen shell is insignificant for the mass and the radius of the'star'. These quantities are then determined approximatively: mass = 1.8 solar masses and radius = 9.2 km. On the contrary if densities of the order of one atom / (10 fm)3 do form a stable hydrogen superfluid phase, we find a large range of possible masses from 1.8 to 375 solar masses. The radii vary accordingly from 9 to 1200 km.

AB - The structure of a spherically symmetric stable dark'star' is discussed, at zero temperature, containing 1) a core of quarks in the deconfined phase and antileptons 2) a shell of hadrons in particular n, p, ? and S- and leptons or antileptons and 3) a shell of hydrogen in the superfluid phase. If the superfluid hydrogen phase goes over into the electromagnetic plasma phase at densities well below one atom / (10 fm)3, as is usually assumed, the hydrogen shell is insignificant for the mass and the radius of the'star'. These quantities are then determined approximatively: mass = 1.8 solar masses and radius = 9.2 km. On the contrary if densities of the order of one atom / (10 fm)3 do form a stable hydrogen superfluid phase, we find a large range of possible masses from 1.8 to 375 solar masses. The radii vary accordingly from 9 to 1200 km.

KW - Dark matter

KW - Quark stars

UR - https://www.scopus.com/pages/publications/85056470427

U2 - 10.22323/1.007.0203

DO - 10.22323/1.007.0203

M3 - Conference article

AN - SCOPUS:85056470427

SN - 1824-8039

VL - 7

JO - Proceedings of Science

JF - Proceedings of Science

Y2 - 12 July 2001 through 18 July 2001

ER -

Stable quark stars beyond neutron stars: Can they account for the missing matter ?

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