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

Peter Minkowski; Sonja Kabana

doi:10.1088/0954-3899/28/7/372

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

Peter Minkowski
, Sonja Kabana

University of Bern

Producción científica: Contribución a una revista › Artículo › 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, Λ and ∑^- 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 approximately: mass = 1.8 solar masses and radius = 9.2 km. In contrast, 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
Número de artículo	372
Páginas (desde-hasta)	2063-2067
Número de páginas	5
Publicación	Journal of Physics G: Nuclear and Particle Physics
Volumen	28
N.º	7
DOI	https://doi.org/10.1088/0954-3899/28/7/372
Estado	Publicada - jul. 2002
Publicado de forma externa	Sí

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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, Λ and ∑- 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 approximately: mass = 1.8 solar masses and radius = 9.2 km. In contrast, 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.",

author = "Peter Minkowski and Sonja Kabana",

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

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