Measurement of the azimuthal anisotropy for charged particle production in sqrt(sNN) = 2.76 TeV lead-lead collisions with the ATLAS detector

Abstract

Differential measurements of charged particle azimuthal anisotropy are presented for lead-lead collisions at sqrt(sNN) = 2.76 TeV with the ATLAS detector at the LHC, based on an integrated luminosity of approximately 8 mb-1. This anisotropy is characterized via a Fourier expansion of the distribution of charged particles in azimuthal angle (phi), with the coefficients vn denoting the magnitude of the anisotropy. Significant v2-v6 values are obtained as a function of transverse momentum (0.5<pT<20 GeV), pseudorapidity (|eta|<2.5) and centrality using an event plane method. The vn values for n>=3 are found to vary weakly with both eta and centrality, and their pT dependencies are found to follow an approximate scaling relation, vn1/n(pT) v21/2(pT). A Fourier analysis of the charged particle pair distribution in relative azimuthal angle (Dphi=phia-phib) is performed to extract the coefficients vn,n=<cos (n Dphi)>. For pairs of charged particles with a large pseudorapidity gap (|Deta=etaa-etab|>2) and one particle with pT<3 GeV, the v2,2-v6,6 values are found to factorize as vn,n(pTa,pTb) ~ vn(pTa)vn(pTb) in central and mid-central events. Such factorization suggests that these values of v2,2-v6,6 are primarily due to the response of the created matter to the fluctuations in the geometry of the initial state. A detailed study shows that the v1,1(pTa,pTb) data are consistent with the combined contributions from a rapidity-even v1 and global momentum conservation. A two-component fit is used to extract the v1 contribution. The extracted v1 is observed to cross zero at pT1.0 GeV, reaches a maximum at 4-5 GeV with a value comparable to that for v3, and decreases at higher pT.