Flow and correlation phenomena measurements in pp, pPb and PbPb collisions at CMS

Abstract: Abstract. The quark-gluon plasma created in high energy collisions of large nuclei exhibits strong anisotropic collective behavior as a nearly perfect fluid, flowing with little frictional resistance or viscosity. It has been investigated extensively over the past years employing two or more particle correlations. An overview of collective flow and particle correlation measurements at CMS as a function of transverse momentum, pseudorapidity, event multiplicity, for both charged hadrons or identified particles … Show more

“…The results of lepton-hadron and lepton-nucleus interactions thus will define very clearly the particle physics background to possible collective effects. For example, recently azimuthal correlations were observed in high multiplicity p+p and p+A as well as in heavy ion reactions (the ridge effect [39,40]), whose origin is currently not entirely clear. If such a ridge effect appears also in e+p and e+A collisions, then most likely this effect is not of a hydrodynamical origin, while if it does not appear in e+p and e+A collisions in the same multiplicity range as in p+p and p+A reactions, than the ridge is more likely a hydrodynamical effect.…”

“…Furthermore, Shuryak and Zahed proposed [38] the application of hydrodynamics for high multiplicity p+p and p+A collisions at CERN LHC. The ridge effect [39,40], i.e. long range azimuthal correlations were observed in high multiplicity p+p and p+A as well as in heavy ion reactions, which also points towards similarities in collectivity, and perhaps the applicability of hydrodynamics can be extended to these systems.…”

Initial Energy Density of √s = 7 and 8 TeV p–p Collisions at the LHC

“…The results of lepton-hadron and lepton-nucleus interactions thus will define very clearly the particle physics background to possible collective effects. For example, recently azimuthal correlations were observed in high multiplicity p+p and p+A as well as in heavy ion reactions (the ridge effect [39,40]), whose origin is currently not entirely clear. If such a ridge effect appears also in e+p and e+A collisions, then most likely this effect is not of a hydrodynamical origin, while if it does not appear in e+p and e+A collisions in the same multiplicity range as in p+p and p+A reactions, than the ridge is more likely a hydrodynamical effect.…”

“…Furthermore, Shuryak and Zahed proposed [38] the application of hydrodynamics for high multiplicity p+p and p+A collisions at CERN LHC. The ridge effect [39,40], i.e. long range azimuthal correlations were observed in high multiplicity p+p and p+A as well as in heavy ion reactions, which also points towards similarities in collectivity, and perhaps the applicability of hydrodynamics can be extended to these systems.…”

Initial Energy Density of √s = 7 and 8 TeV p–p Collisions at the LHC