Physics
LHC Detector Active Right Now Analyzing Quark-Gluon Plasma
Mark Hoffman
First Posted: Jan 24, 2013 01:22 PM EST
Since a new round of collisions was successfully started four days ago in the Large Hadron Collider, this time between protons and heavy lead ions, the large detectors of the LHC experiments ALICE, ATLAS, CMS and LHCb are analyzing and recording the resulting particles. Among them, ALICE is specialized in scrutinizing heavy-ion collisions to investigate the properties of the elusive quark-gluon plasma, the primordial state of matter that existed in the first moments after the big bang, just before the phase transition to matter made of nucleons (protons and neutrons).
The current run of colliding protons with lead ions, which are made of 208 nucleons, is done in order to compare the effects to those of lead-lead collisions.
To study quark-gluon plasma, physicists need to create the high-temperature matter that is formed in the collisions of heavy ions. In lead-lead collisions ALICE physicists can deduce some properties of the plasma - from its effect on particles moving through it, for instance. But they also need to distinguish effects caused by the hot plasma from effects caused by the cold nuclear matter that makes up lead nuclei.
"The lead-proton run will help us to understand the complexity of the lead-lead interaction at many levels," says ALICE physicist Despina Hatzifotiadou. "There is somehow a missing link in the game: We know that the configurations of the quarks and gluons that make up the protons and neutrons of the incoming lead nucleus can be somewhat different from the configurations of the quarks and gluons of the incoming protons. We want to measure if part of the effects we find when comparing lead-lead and proton-proton collisions is due to this configuration difference rather than the formation of the plasma. Proton-lead collisions, where we do not expect formation of quark-gluon plasma but we do have an incoming lead nucleus, are an ideal tool for this study."
Hatzifotiadou says the data from the lead-proton collisions will represent an ultimate benchmark to fully understand results from lead-lead collisions. "It will allow physicists to decouple the cold nuclear matter effects and thus will shed light on our study of the quark-gluon plasma," she says.
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First Posted: Jan 24, 2013 01:22 PM EST
Since a new round of collisions was successfully started four days ago in the Large Hadron Collider, this time between protons and heavy lead ions, the large detectors of the LHC experiments ALICE, ATLAS, CMS and LHCb are analyzing and recording the resulting particles. Among them, ALICE is specialized in scrutinizing heavy-ion collisions to investigate the properties of the elusive quark-gluon plasma, the primordial state of matter that existed in the first moments after the big bang, just before the phase transition to matter made of nucleons (protons and neutrons).
The current run of colliding protons with lead ions, which are made of 208 nucleons, is done in order to compare the effects to those of lead-lead collisions.
To study quark-gluon plasma, physicists need to create the high-temperature matter that is formed in the collisions of heavy ions. In lead-lead collisions ALICE physicists can deduce some properties of the plasma - from its effect on particles moving through it, for instance. But they also need to distinguish effects caused by the hot plasma from effects caused by the cold nuclear matter that makes up lead nuclei.
"The lead-proton run will help us to understand the complexity of the lead-lead interaction at many levels," says ALICE physicist Despina Hatzifotiadou. "There is somehow a missing link in the game: We know that the configurations of the quarks and gluons that make up the protons and neutrons of the incoming lead nucleus can be somewhat different from the configurations of the quarks and gluons of the incoming protons. We want to measure if part of the effects we find when comparing lead-lead and proton-proton collisions is due to this configuration difference rather than the formation of the plasma. Proton-lead collisions, where we do not expect formation of quark-gluon plasma but we do have an incoming lead nucleus, are an ideal tool for this study."
Hatzifotiadou says the data from the lead-proton collisions will represent an ultimate benchmark to fully understand results from lead-lead collisions. "It will allow physicists to decouple the cold nuclear matter effects and thus will shed light on our study of the quark-gluon plasma," she says.
See Now: NASA's Juno Spacecraft's Rendezvous With Jupiter's Mammoth Cyclone