Cosmic separation of phases
- 15 July 1984
- journal article
- research article
- Published by American Physical Society (APS) in Physical Review D
- Vol. 30 (2), 272-285
- https://doi.org/10.1103/physrevd.30.272
Abstract
A first-order QCD phase transition that occurred reversibly in the early universe would lead to a surprisingly rich cosmological scenario. Although observable consequences would not necessarily survive, it is at least conceivable that the phase transition would concentrate most of the quark excess in dense, invisible quark nuggets, providing an explanation for the dark matter in terms of QCD effects only. This possibility is viable only if quark matter has energy per baryon less than 938 MeV. Two related issues are considered in appendices: the possibility that neutron stars generate a quark-matter component of cosmic rays, and the possibility that the QCD phase transition may have produced a detectable gravitational signal.Keywords
This publication has 80 references indexed in Scilit:
- Finite-temperature QCD at largePhysical Review D, 1984
- Remarks on the chiral phase transition in chromodynamicsPhysical Review D, 1984
- Effects of quarks on SU(N) deconfinement phase transitionsPhysics Letters B, 1983
- Deconfining and chiral phase transitions in quantum chromodynamics at finite temperatureNuclear Physics B, 1983
- Large-Quantum Chromodynamics at Finite TemperaturePhysical Review Letters, 1983
- Critical behavior at finite-temperature confinement transitionsNuclear Physics B, 1982
- First-order phase transition in the SU(3) gauge theory at finite temperaturePhysical Review D, 1982
- Phase transition ofSU(3) gauge theory at finite temperatureThe European Physical Journal C, 1981
- Lattice models of quark confinement at high temperaturePhysical Review D, 1979
- Thermal properties of gauge fields and quark liberationPhysics Letters B, 1978