The order of the quantum chromodynamics transition predicted by the standard model of particle physics
A universal transition The standard model of particle physics predicts two phase transitions that are relevant for the evolution of the early Universe. One, the quantum chromodynamics transition, involves the strong force that binds quarks into protons and neutrons. Despite much theoretical effort,...
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| Veröffentlicht in: | Nature 2006-10, Vol.443 (7112), p.675-678 |
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| description | A universal transition
The standard model of particle physics predicts two phase transitions that are relevant for the evolution of the early Universe. One, the quantum chromodynamics transition, involves the strong force that binds quarks into protons and neutrons. Despite much theoretical effort, the nature of this transition remains ambiguous. Now Aoki
et al
. report computationally demanding calculations that suggest that there was no true phase transition. Instead, an analytic crossover took place, involving a rapid, continuous change with temperature as opposed to a jump. This means that it will be difficult to find experimental evidence of a transition from astronomical observations.
The standard model of particle physics predicts two transitions that are relevant for the evolution of the early Universe. Computationally demanding calculations now reveal that a real phase transition did not occur, but rather an analytic crossover, involving a rapid change (as opposed to a jump) as the temperature varies.
Quantum chromodynamics (QCD) is the theory of the strong interaction, explaining (for example) the binding of three almost massless quarks into a much heavier proton or neutron—and thus most of the mass of the visible Universe. The standard model of particle physics predicts a QCD-related transition that is relevant for the evolution of the early Universe. At low temperatures, the dominant degrees of freedom are colourless bound states of hadrons (such as protons and pions). However, QCD is asymptotically free, meaning that at high energies or temperatures the interaction gets weaker and weaker
1
,
2
, causing hadrons to break up. This behaviour underlies the predicted cosmological transition between the low-temperature hadronic phase and a high-temperature quark–gluon plasma phase (for simplicity, we use the word ‘phase’ to characterize regions with different dominant degrees of freedom). Despite enormous theoretical effort, the nature of this finite-temperature QCD transition (that is, first-order, second-order or analytic crossover) remains ambiguous. Here we determine the nature of the QCD transition using computationally demanding lattice calculations for physical quark masses. Susceptibilities are extrapolated to vanishing lattice spacing for three physical volumes, the smallest and largest of which differ by a factor of five. This ensures that a true transition should result in a dramatic increase of the susceptibilities. No such behaviour is |
| doi_str_mv | 10.1038/nature05120 |
| format | Article |
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The standard model of particle physics predicts two phase transitions that are relevant for the evolution of the early Universe. One, the quantum chromodynamics transition, involves the strong force that binds quarks into protons and neutrons. Despite much theoretical effort, the nature of this transition remains ambiguous. Now Aoki
et al
. report computationally demanding calculations that suggest that there was no true phase transition. Instead, an analytic crossover took place, involving a rapid, continuous change with temperature as opposed to a jump. This means that it will be difficult to find experimental evidence of a transition from astronomical observations.
The standard model of particle physics predicts two transitions that are relevant for the evolution of the early Universe. Computationally demanding calculations now reveal that a real phase transition did not occur, but rather an analytic crossover, involving a rapid change (as opposed to a jump) as the temperature varies.
Quantum chromodynamics (QCD) is the theory of the strong interaction, explaining (for example) the binding of three almost massless quarks into a much heavier proton or neutron—and thus most of the mass of the visible Universe. The standard model of particle physics predicts a QCD-related transition that is relevant for the evolution of the early Universe. At low temperatures, the dominant degrees of freedom are colourless bound states of hadrons (such as protons and pions). However, QCD is asymptotically free, meaning that at high energies or temperatures the interaction gets weaker and weaker
1
,
2
, causing hadrons to break up. This behaviour underlies the predicted cosmological transition between the low-temperature hadronic phase and a high-temperature quark–gluon plasma phase (for simplicity, we use the word ‘phase’ to characterize regions with different dominant degrees of freedom). Despite enormous theoretical effort, the nature of this finite-temperature QCD transition (that is, first-order, second-order or analytic crossover) remains ambiguous. Here we determine the nature of the QCD transition using computationally demanding lattice calculations for physical quark masses. Susceptibilities are extrapolated to vanishing lattice spacing for three physical volumes, the smallest and largest of which differ by a factor of five. This ensures that a true transition should result in a dramatic increase of the susceptibilities. No such behaviour is observed: our finite-size scaling analysis shows that the finite-temperature QCD transition in the hot early Universe was not a real phase transition, but an analytic crossover (involving a rapid change, as opposed to a jump, as the temperature varied). As such, it will be difficult to find experimental evidence of this transition from astronomical observations.</description><identifier>ISSN: 0028-0836</identifier><identifier>EISSN: 1476-4687</identifier><identifier>EISSN: 1476-4679</identifier><identifier>DOI: 10.1038/nature05120</identifier><identifier>PMID: 17035999</identifier><identifier>CODEN: NATUAS</identifier><language>eng</language><publisher>London: Nature Publishing Group UK</publisher><subject>Cosmology ; Crossovers ; Degrees of freedom ; Exact sciences and technology ; Hadrons ; High temperature ; Humanities and Social Sciences ; letter ; Low temperature ; Mathematical analysis ; Mathematical models ; multidisciplinary ; Particle physics ; Phase transformations ; Phase transitions ; Physics ; Quantum chromodynamics ; Quantum theory ; Science ; Science (multidisciplinary) ; Specific theories and interaction models; particle systematics ; Temperature effects ; The physics of elementary particles and fields ; Universe</subject><ispartof>Nature, 2006-10, Vol.443 (7112), p.675-678</ispartof><rights>Springer Nature Limited 2006</rights><rights>2007 INIST-CNRS</rights><rights>COPYRIGHT 2006 Nature Publishing Group</rights><rights>Copyright Nature Publishing Group Oct 12, 2006</rights><lds50>peer_reviewed</lds50><woscitedreferencessubscribed>false</woscitedreferencessubscribed><citedby>FETCH-LOGICAL-c718t-14ea0e6412b147c94853f246137b97f1556cc08639621b3285d0ca3275d34a573</citedby><cites>FETCH-LOGICAL-c718t-14ea0e6412b147c94853f246137b97f1556cc08639621b3285d0ca3275d34a573</cites></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><linktopdf>$$Uhttps://link.springer.com/content/pdf/10.1038/nature05120$$EPDF$$P50$$Gspringer$$H</linktopdf><linktohtml>$$Uhttps://link.springer.com/10.1038/nature05120$$EHTML$$P50$$Gspringer$$H</linktohtml><link.rule.ids>314,776,780,27901,27902,41464,42533,51294</link.rule.ids><backlink>$$Uhttp://pascal-francis.inist.fr/vibad/index.php?action=getRecordDetail&idt=18163781$$DView record in Pascal Francis$$Hfree_for_read</backlink><backlink>$$Uhttps://www.ncbi.nlm.nih.gov/pubmed/17035999$$D View this record in MEDLINE/PubMed$$Hfree_for_read</backlink></links><search><creatorcontrib>Aoki, Y.</creatorcontrib><creatorcontrib>Endrődi, G.</creatorcontrib><creatorcontrib>Fodor, Z.</creatorcontrib><creatorcontrib>Katz, S. D.</creatorcontrib><creatorcontrib>Szabó, K. K.</creatorcontrib><title>The order of the quantum chromodynamics transition predicted by the standard model of particle physics</title><title>Nature</title><addtitle>Nature</addtitle><addtitle>Nature</addtitle><description>A universal transition
The standard model of particle physics predicts two phase transitions that are relevant for the evolution of the early Universe. One, the quantum chromodynamics transition, involves the strong force that binds quarks into protons and neutrons. Despite much theoretical effort, the nature of this transition remains ambiguous. Now Aoki
et al
. report computationally demanding calculations that suggest that there was no true phase transition. Instead, an analytic crossover took place, involving a rapid, continuous change with temperature as opposed to a jump. This means that it will be difficult to find experimental evidence of a transition from astronomical observations.
The standard model of particle physics predicts two transitions that are relevant for the evolution of the early Universe. Computationally demanding calculations now reveal that a real phase transition did not occur, but rather an analytic crossover, involving a rapid change (as opposed to a jump) as the temperature varies.
Quantum chromodynamics (QCD) is the theory of the strong interaction, explaining (for example) the binding of three almost massless quarks into a much heavier proton or neutron—and thus most of the mass of the visible Universe. The standard model of particle physics predicts a QCD-related transition that is relevant for the evolution of the early Universe. At low temperatures, the dominant degrees of freedom are colourless bound states of hadrons (such as protons and pions). However, QCD is asymptotically free, meaning that at high energies or temperatures the interaction gets weaker and weaker
1
,
2
, causing hadrons to break up. This behaviour underlies the predicted cosmological transition between the low-temperature hadronic phase and a high-temperature quark–gluon plasma phase (for simplicity, we use the word ‘phase’ to characterize regions with different dominant degrees of freedom). Despite enormous theoretical effort, the nature of this finite-temperature QCD transition (that is, first-order, second-order or analytic crossover) remains ambiguous. Here we determine the nature of the QCD transition using computationally demanding lattice calculations for physical quark masses. Susceptibilities are extrapolated to vanishing lattice spacing for three physical volumes, the smallest and largest of which differ by a factor of five. This ensures that a true transition should result in a dramatic increase of the susceptibilities. No such behaviour is observed: our finite-size scaling analysis shows that the finite-temperature QCD transition in the hot early Universe was not a real phase transition, but an analytic crossover (involving a rapid change, as opposed to a jump, as the temperature varied). As such, it will be difficult to find experimental evidence of this transition from astronomical observations.</description><subject>Cosmology</subject><subject>Crossovers</subject><subject>Degrees of freedom</subject><subject>Exact sciences and technology</subject><subject>Hadrons</subject><subject>High temperature</subject><subject>Humanities and Social Sciences</subject><subject>letter</subject><subject>Low temperature</subject><subject>Mathematical analysis</subject><subject>Mathematical models</subject><subject>multidisciplinary</subject><subject>Particle physics</subject><subject>Phase transformations</subject><subject>Phase transitions</subject><subject>Physics</subject><subject>Quantum chromodynamics</subject><subject>Quantum theory</subject><subject>Science</subject><subject>Science (multidisciplinary)</subject><subject>Specific theories and interaction models; particle systematics</subject><subject>Temperature effects</subject><subject>The physics of elementary particles and fields</subject><subject>Universe</subject><issn>0028-0836</issn><issn>1476-4687</issn><issn>1476-4679</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2006</creationdate><recordtype>article</recordtype><sourceid>8G5</sourceid><sourceid>BEC</sourceid><sourceid>BENPR</sourceid><sourceid>GUQSH</sourceid><sourceid>M2O</sourceid><recordid>eNqF0s2L1DAUAPAiijuunrxLEVYU7ZrvpMdh8GNhUdARjyVNX2eytGknScH57806A7Mjo0sOIcnvvZCXl2XPMbrEiKr3TsfJA-KYoAfZDDMpCiaUfJjNECKqQIqKs-xJCDcIJSTZ4-wMS0R5WZazrF2uIR98Az4f2jymxWbSLk59btZ-6Idm63RvTcij1y7YaAeXjx4aayI0eb39ExKido32TZ48dLeJRu2jNR3k43obUvjT7FGruwDP9vN59uPjh-Xic3H99dPVYn5dGIlVLDADjUAwTOr0DlMyxWlLmMBU1qVsMefCGKQELQXBNSWKN8hoSiRvKNNc0vPs1S7v6IfNBCFWvQ0Guk47GKZQCVWyUnJyL6SCKEIZSvD1fyGWnHKmCBH3U6QILhFlLNGXf9GbYfIulaYiiHEiCOEJFTu00h1U1rVD-gSzAgded4OD1qbtOVacMYkkPSQ98ma0m-ouujyB0mgg_fPJrG-OApKJ8Cuu9BRCdfX927F9-287X_5cfDmpjR9C8NBWo7e99ttUqeq2tas7rZ30i33JprqH5mD3vZzAxR7oYHTXpoY1NhycwoJKhZN7t3MhHbkV-EPtT937GykQCvk</recordid><startdate>20061012</startdate><enddate>20061012</enddate><creator>Aoki, Y.</creator><creator>Endrődi, G.</creator><creator>Fodor, Z.</creator><creator>Katz, S. 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K.</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c718t-14ea0e6412b147c94853f246137b97f1556cc08639621b3285d0ca3275d34a573</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2006</creationdate><topic>Cosmology</topic><topic>Crossovers</topic><topic>Degrees of freedom</topic><topic>Exact sciences and technology</topic><topic>Hadrons</topic><topic>High temperature</topic><topic>Humanities and Social Sciences</topic><topic>letter</topic><topic>Low temperature</topic><topic>Mathematical analysis</topic><topic>Mathematical models</topic><topic>multidisciplinary</topic><topic>Particle physics</topic><topic>Phase transformations</topic><topic>Phase transitions</topic><topic>Physics</topic><topic>Quantum chromodynamics</topic><topic>Quantum theory</topic><topic>Science</topic><topic>Science (multidisciplinary)</topic><topic>Specific theories and interaction models; particle systematics</topic><topic>Temperature effects</topic><topic>The physics of elementary particles and fields</topic><topic>Universe</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Aoki, Y.</creatorcontrib><creatorcontrib>Endrődi, G.</creatorcontrib><creatorcontrib>Fodor, Z.</creatorcontrib><creatorcontrib>Katz, S. 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Academic</collection><jtitle>Nature</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Aoki, Y.</au><au>Endrődi, G.</au><au>Fodor, Z.</au><au>Katz, S. D.</au><au>Szabó, K. K.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>The order of the quantum chromodynamics transition predicted by the standard model of particle physics</atitle><jtitle>Nature</jtitle><stitle>Nature</stitle><addtitle>Nature</addtitle><date>2006-10-12</date><risdate>2006</risdate><volume>443</volume><issue>7112</issue><spage>675</spage><epage>678</epage><pages>675-678</pages><issn>0028-0836</issn><eissn>1476-4687</eissn><eissn>1476-4679</eissn><coden>NATUAS</coden><abstract>A universal transition
The standard model of particle physics predicts two phase transitions that are relevant for the evolution of the early Universe. One, the quantum chromodynamics transition, involves the strong force that binds quarks into protons and neutrons. Despite much theoretical effort, the nature of this transition remains ambiguous. Now Aoki
et al
. report computationally demanding calculations that suggest that there was no true phase transition. Instead, an analytic crossover took place, involving a rapid, continuous change with temperature as opposed to a jump. This means that it will be difficult to find experimental evidence of a transition from astronomical observations.
The standard model of particle physics predicts two transitions that are relevant for the evolution of the early Universe. Computationally demanding calculations now reveal that a real phase transition did not occur, but rather an analytic crossover, involving a rapid change (as opposed to a jump) as the temperature varies.
Quantum chromodynamics (QCD) is the theory of the strong interaction, explaining (for example) the binding of three almost massless quarks into a much heavier proton or neutron—and thus most of the mass of the visible Universe. The standard model of particle physics predicts a QCD-related transition that is relevant for the evolution of the early Universe. At low temperatures, the dominant degrees of freedom are colourless bound states of hadrons (such as protons and pions). However, QCD is asymptotically free, meaning that at high energies or temperatures the interaction gets weaker and weaker
1
,
2
, causing hadrons to break up. This behaviour underlies the predicted cosmological transition between the low-temperature hadronic phase and a high-temperature quark–gluon plasma phase (for simplicity, we use the word ‘phase’ to characterize regions with different dominant degrees of freedom). Despite enormous theoretical effort, the nature of this finite-temperature QCD transition (that is, first-order, second-order or analytic crossover) remains ambiguous. Here we determine the nature of the QCD transition using computationally demanding lattice calculations for physical quark masses. Susceptibilities are extrapolated to vanishing lattice spacing for three physical volumes, the smallest and largest of which differ by a factor of five. This ensures that a true transition should result in a dramatic increase of the susceptibilities. No such behaviour is observed: our finite-size scaling analysis shows that the finite-temperature QCD transition in the hot early Universe was not a real phase transition, but an analytic crossover (involving a rapid change, as opposed to a jump, as the temperature varied). As such, it will be difficult to find experimental evidence of this transition from astronomical observations.</abstract><cop>London</cop><pub>Nature Publishing Group UK</pub><pmid>17035999</pmid><doi>10.1038/nature05120</doi><tpages>4</tpages></addata></record> |
| fulltext | fulltext |
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| ispartof | Nature, 2006-10, Vol.443 (7112), p.675-678 |
| issn | 0028-0836 1476-4687 1476-4679 |
| language | eng |
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| source | SpringerLink Journals; Nature Journals Online |
| subjects | Cosmology Crossovers Degrees of freedom Exact sciences and technology Hadrons High temperature Humanities and Social Sciences letter Low temperature Mathematical analysis Mathematical models multidisciplinary Particle physics Phase transformations Phase transitions Physics Quantum chromodynamics Quantum theory Science Science (multidisciplinary) Specific theories and interaction models particle systematics Temperature effects The physics of elementary particles and fields Universe |
| title | The order of the quantum chromodynamics transition predicted by the standard model of particle physics |
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