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{{Short description|A phase transition for the whole universe}}
A '''cosmological phase transition''' is an overall change in the [[state of matter]] across the whole universe. The success of the [[Big Bang]] model led researchers to conjecture possible cosmological phase transitions taking place in the very early universe, at a time when it was much hotter and denser than today.<ref>{{cite journal |last1=Guth |first1=Alan H. |last2=Tye |first2=S.H. H. |title=Phase Transitions and Magnetic Monopole Production in the Very Early Universe |journal=Phys. Rev. Lett. |date=1980 |volume=44 |issue=10 |pages=631–635 |doi=10.1103/PhysRevLett.44.631|bibcode=1980PhRvL..44..631G |osti=1447535 }}</ref><ref name="witten-1984">{{Cite journal |last=Witten |first=Edward |date=1984-07-15 |title=Cosmic separation of phases |url=https://link.aps.org/doi/10.1103/PhysRevD.30.272 |journal=Physical Review D |language=en |volume=30 |issue=2 |pages=272–285 |bibcode=1981NuPhB.177..477W |doi=10.1103/PhysRevD.30.272 |issn=0556-2821|url-access=subscription }}</ref>
Any cosmological phase transition may have left signals which are observable today, even if it took place in the first moments after the Big Bang, when the universe was [[cosmic microwave background|opaque to light]].<ref>{{cite journal |last1=Kibble |first1=T. W. B. |title=Some implications of a Cosmological Phase Transition |journal=Phys. Rep. |date=1980 |volume=67 |issue=1 |pages=183–199 |doi=10.1016/0370-1573(80)90091-5|bibcode=1980PhR....67..183K }}</ref>
== Character ==
The [[Standard
A phase transition can be related to a difference in symmetry between the two states. For example liquid is isotropic but solid water, [[ice]], has directions with different properties. The two states have different energy: ice has less energy than liquid water.
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Second order transitions are continuous rather than abrupt and are less likely to leave observable imprints cosmic structures.<ref name=Manzudar-2019/>
==Within the
The [[Standard Model]] of particle physics contains three [[fundamental force]]s, the [[electromagnetic force]], the [[weak force]] and the [[strong force]]. Shortly after the Big Bang, the extremely high temperatures may have modified the character of these forces. While these three forces act differently today, it has been conjectured that they may have been unified in the high temperatures of the early universe.<ref name="georgi-glashow">{{cite journal |last1=Georgi |first1=H. |last2=Glashow |first2=S. L. |title=Unity of All Elementary Forces |journal=Phys. Rev. Lett. |date=1974 |volume=32 |pages=438–441 |doi=10.1103/PhysRevLett.32.438}}</ref><ref name="weinberg-gauge">{{cite journal |last1=Weinberg |first1=Steven |title=Gauge and Global Symmetries at High Temperature |journal=Phys. Rev. D |date=1974 |volume=9 |issue=12 |pages=3357–3378|doi=10.1103/PhysRevD.9.3357 |bibcode=1974PhRvD...9.3357W }}</ref>
===QCD phase transition===
{{for|particle physics|QCD matter#Phase_diagram}}
[[File:QCD phase diagram.png|thumb|300px|right|Conjectured form of the [[QCD matter#Phase_diagram| phase diagram of QCD matter]], with temperature on the vertical axis and quark [[chemical potential]] on the horizontal axis, both in mega-[[electron volt]]s.<ref name='RMP'>{{cite journal|author1=Alford, Mark G.|author2=Schmitt, Andreas|author3=Rajagopal, Krishna|author4=Schäfer, Thomas|title=Color superconductivity in dense quark matter|arxiv=0709.4635 |journal=Reviews of Modern Physics |volume=80|issue=4 |pages=1455–1515 |year=2008|doi=10.1103/RevModPhys.80.1455|bibcode=2008RvMP...80.1455A|s2cid=14117263}}</ref>]]
The strong force binds together [[quarks]] into [[protons]] and [[neutrons]], in a phenomenon known as [[color confinement]]. However, at sufficiently high temperatures, protons and neutrons disassociate into free quarks. This phase transition is also called the quark–hadron transition.<ref name=Peacock-1998>{{Cite book |last=Peacock |first=J. A. |url=https://www.cambridge.org/core/product/identifier/9780511804533/type/book |title=Cosmological Physics |date=1998-12-28 |publisher=Cambridge University Press |isbn=978-0-521-41072-4 |edition=1 |doi=10.1017/cbo9780511804533}}</ref>{{rp|305}} Studies of this transition based on [[lattice QCD]] have demonstrated that it would have taken place at a temperature of approximately 155 [[MeV]], and would have been a smooth crossover transition.<ref name="aoki-qcd">{{cite journal |last1=Aoki |first1=Y. |last2=Endrodi |first2=G. |last3=Fodor |first3=Z. |last4=Katz |first4=S. D. |last5=Szabo |first5=K. K. |title=The order of the quantum chromodynamics transition predicted by the standard model of particle physics |journal=Nature |date=2006 |volume=443 |issue=7112 |pages=675–678 |doi=10.1038/nature05120|pmid=17035999 |arxiv=hep-lat/0611014 |bibcode=2006Natur.443..675A |s2cid=261693972 }}</ref> In the early universe the chemical potential of baryons is assumed to be near zero and the transition near 170MeV converts a quark-gluon plasma to a hadron gas.<ref name=Manzudar-2019/>{{rp|25}}
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===Electroweak phase transition===
The electroweak phase transition marks the moment when the [[Higgs mechanism]]
Lattice studies of the electroweak model have found the transition to be a smooth crossover, taking place at a temperature of {{nobr| 159.5 ± 1.5 [[GeV]].}}<ref name=donofrio-rummukainen>▼
▲Lattice studies of the electroweak model have found the transition to be a smooth crossover, taking place at {{nobr| 159.5 ± 1.5 [[GeV]].}}<ref name=donofrio-rummukainen>
{{cite journal
|last1 = d'Onofrio |first1 = Michela
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|bibcode=2013JCAP...01..012C
}}
</ref> The [[electroweak baryogenesis]] model may explain the [[baryon asymmetry]] in the universe, the observation that the amount of matter vastly exceeds the amount of
==Beyond the Standard Model==
If the three forces of the Standard Model are unified in a [[Grand Unified Theory]], then there would have been a cosmological phase transition at even higher temperatures, corresponding to the moment when the forces first separated out.<ref name="georgi-glashow" /><ref name="weinberg-gauge" /> A GUT transition that breaks this hypothetical unified state into the Standard model's <math>SU(3)\otimes SU(2)\otimes U(1)</math> symmetry may be responsible for the observed excess of matter over antimatter.<ref name=Peacock-1998/>{{rp|305}} Cosmological phase transitions may also have taken place in a dark or [[hidden sector]], amongst particles and fields that are only very weakly coupled to visible matter.
<ref name="Schwaller2015">{{cite journal |last1=Schwaller |first1=Pedro |title=Gravitational waves from a dark phase transition |journal=Phys. Rev. Lett. |date=2015 |volume=115 |issue=18 |pages=181101 |doi=10.1103/PhysRevLett.115.181101|pmid=26565451 |arxiv=1504.07263 |bibcode=2015PhRvL.115r1101S |doi-access=free }}</ref>
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