Intersecting Storage Rings | CERN, 1971–1984 |
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Super Proton Synchrotron | CERN, 1981–1984 |
ISABELLE | BNL, cancelled in 1983 |
Tevatron | Fermilab, 1987–2011 |
Relativistic Heavy Ion Collider | BNL, 2000–present |
Superconducting Super Collider | Cancelled in 1993 |
Large Hadron Collider | CERN, 2009–present |
Future Circular Collider | Proposed |
The Relativistic Heavy Ion Collider (RHIC /ˈrɪk/) is one of only two operating heavy-ion colliders, and the only spin-polarized proton collider ever built. Located at Brookhaven National Laboratory (BNL) in Upton, New York, and used by an international team of researchers, it is the only operating particle collider in the US. By using RHIC to collide ions traveling at relativistic speeds, physicists study the primordial form of matter that existed in the universe shortly after the Big Bang. By colliding spin-polarized protons, the spin structure of the proton is explored.
RHIC is now the second-highest-energy heavy-ion collider in the world. As of November 7, 2010, the Large Hadron Collider (LHC) has collided heavy ions of lead at higher energies than RHIC. The LHC operating time for ions (lead-lead and lead-proton collisions) is limited to about one month per year.
In 2010, RHIC physicists published results of temperature measurements from earlier experiments which concluded that temperatures in excess of 345 MeV (4 terakelvins or 7 trillion degrees Fahrenheit) had been achieved in gold ion collisions, and that these collision temperatures resulted in the breakdown of "normal matter" and the creation of a liquid-like quark–gluon plasma.
RHIC is an intersecting storage ring particle accelerator. Two independent rings (arbitrarily denoted as "Blue" and "Yellow" rings) circulate heavy ions and/or protons in opposite directions and allow a virtually free choice of colliding positively charged particles (the eRHIC upgrade will allow collisions between positively and negatively charged particles). The RHIC double storage ring is itself hexagonally shaped and long in circumference, with curved edges in which stored particles are deflected and focused by 1,740 3834 msuperconducting magnets using niobium-titanium conductors. The dipole magnets operate at T. The six interaction points (between the particles circulating in the two rings) are at the middle of the six relatively straight sections, where the two rings cross, allowing the particles to collide. The interaction points are enumerated by clock positions, with the injection near 6 o'clock. Two large experiments, STAR and PHENIX, are located at 6 and 8 o'clock respectively. 3.45