| 释义 |
Definition of quark-gluon plasma in US English: quark-gluon plasmanoun A hypothetical, highly energized form of matter that contains unbound quarks and gluons, believed to have been present ten millionths of a second after the Big Bang. Example sentencesExamples - It has been host to Nobel Prize-winning research, scientists have discovered neutral currents, sorted the anti-matter from the matter and created an entirely new form of matter - quark-gluon plasma - last seen just after the big bang.
- They are trying to get subatomic particles called quarks and gluons to separate from the nuclei and form a superheated quark-gluon plasma, 40 billion times hotter than room temperature.
- The first measurements of head-on collisions at RHIC energies, with nuclei as heavy as gold, have already taken us a major step toward the long-sought quark-gluon plasma.
- These extreme conditions were expected to have liberated quarks and gluons from their quantum prisons inside the gold protons and neutrons, producing a primordial particle soup - quark-gluon plasma.
- At low temperatures, quarks are confined in hadrons, whereas at higher temperatures they form a quark-gluon plasma.
- In so doing they have generated the long sought quark-gluon plasma in which quarks are ‘free’.
- ‘The current findings don't rule out the possibility that this new state of matter is in fact a form of the quark-gluon plasma, just different from what had been theorized,’ Aronson said.
- Theorists predict that just after the big bang, there would have existed a quark-gluon plasma, and some theorists argue that this is what the researchers have discovered.
- The first stage in the creation of these new particles, like the first stage of the creation of matter in the Big Bang, is thought to be the quark-gluon plasma.
- In theory, very hot, dense matter can dissolve into a mass of loosely associated quarks and gluons known as a quark-gluon plasma, or QGP, where particles would behave differently than they do in normal nuclei.
- The stunning implication is that a quark-gluon plasma had been present in the gold-gold experiments.
- In three spatial dimensions, it is a close relative of the quark-gluon plasma, the super-hot state of matter that hasn't existed since the tiniest fraction of a second after the big bang that started the universe.
- The universe was very likely such a quark-gluon plasma for a brief moment after the Big Bang.
- By using experiments that involve millions of particle collisions, researchers hope to find unambiguous evidence of quark-gluon plasma.
- That is, the energy of the collisions was predicted to be sufficient to ‘melt’ the protons and neutrons and produce a hot ‘soup’ of free quarks and gluons, dubbed the quark-gluon plasma.
- While the presence of quark-gluon plasma has not been confirmed, the scientists agree that the matter they observed is different from anything else previously seen.
- Here I must apply the principles of nuclear dynamics including inferences of quark-gluon plasma to argue Hawthorn's case.
- Among the most exotic forms of matter ever concocted is the quark-gluon plasma, newly created by physicists at the Brookhaven National Laboratory, a particle-accelerator facility on New York's Long Island.
- This marked the first major milestone in the search for a quark-gluon plasma or QGP.
- The scientists respond that catastrophe is extremely unlikely, and that the tiny chance of disaster is outweighed by all the benefits to humanity to flow from creating a quark-gluon plasma.
Definition of quark-gluon plasma in US English: quark-gluon plasmanoun A hypothetical, highly energized form of matter that contains unbound quarks and gluons, believed to have been present ten millionths of a second after the Big Bang. Example sentencesExamples - In three spatial dimensions, it is a close relative of the quark-gluon plasma, the super-hot state of matter that hasn't existed since the tiniest fraction of a second after the big bang that started the universe.
- At low temperatures, quarks are confined in hadrons, whereas at higher temperatures they form a quark-gluon plasma.
- Theorists predict that just after the big bang, there would have existed a quark-gluon plasma, and some theorists argue that this is what the researchers have discovered.
- The universe was very likely such a quark-gluon plasma for a brief moment after the Big Bang.
- They are trying to get subatomic particles called quarks and gluons to separate from the nuclei and form a superheated quark-gluon plasma, 40 billion times hotter than room temperature.
- Among the most exotic forms of matter ever concocted is the quark-gluon plasma, newly created by physicists at the Brookhaven National Laboratory, a particle-accelerator facility on New York's Long Island.
- The first stage in the creation of these new particles, like the first stage of the creation of matter in the Big Bang, is thought to be the quark-gluon plasma.
- In so doing they have generated the long sought quark-gluon plasma in which quarks are ‘free’.
- That is, the energy of the collisions was predicted to be sufficient to ‘melt’ the protons and neutrons and produce a hot ‘soup’ of free quarks and gluons, dubbed the quark-gluon plasma.
- The scientists respond that catastrophe is extremely unlikely, and that the tiny chance of disaster is outweighed by all the benefits to humanity to flow from creating a quark-gluon plasma.
- ‘The current findings don't rule out the possibility that this new state of matter is in fact a form of the quark-gluon plasma, just different from what had been theorized,’ Aronson said.
- It has been host to Nobel Prize-winning research, scientists have discovered neutral currents, sorted the anti-matter from the matter and created an entirely new form of matter - quark-gluon plasma - last seen just after the big bang.
- This marked the first major milestone in the search for a quark-gluon plasma or QGP.
- While the presence of quark-gluon plasma has not been confirmed, the scientists agree that the matter they observed is different from anything else previously seen.
- Here I must apply the principles of nuclear dynamics including inferences of quark-gluon plasma to argue Hawthorn's case.
- In theory, very hot, dense matter can dissolve into a mass of loosely associated quarks and gluons known as a quark-gluon plasma, or QGP, where particles would behave differently than they do in normal nuclei.
- The first measurements of head-on collisions at RHIC energies, with nuclei as heavy as gold, have already taken us a major step toward the long-sought quark-gluon plasma.
- These extreme conditions were expected to have liberated quarks and gluons from their quantum prisons inside the gold protons and neutrons, producing a primordial particle soup - quark-gluon plasma.
- By using experiments that involve millions of particle collisions, researchers hope to find unambiguous evidence of quark-gluon plasma.
- The stunning implication is that a quark-gluon plasma had been present in the gold-gold experiments.
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