Universal Centrality and Collision Energy Trends for v2 Measurements From 2D Angular Correlations

Abstract

We have measured the pt-integrated quadrupole component of two-particle azimuth correlations (related to quantity v2, denoted in this case by v2 \2D\) via two-dimensional (2D) angular autocorrelations on (η, φ) for unidentified hadrons in Au-Au collisions at 62 and 200 GeV. The 2D autocorrelation provides a method to remove non-quadrupole contributions to v2 (conventionally termed ``nonflow'') under the assumption that such processes produce significant dependence on pair-wise relative η within the detector acceptance. We hypothesize, based on empirical observations, that non-quadrupole contributions are dominated by minijets or minimum-bias jets. Using the optical Glauber eccentricity model for initial-state geometry we find simple and accurate universal energy and centrality trends for the quadrupole component. Centrality trends are determined only by the initial state (impact parameter b and center-of-mass energy sNN). There is no apparent dependence on evolving system dynamics (e.g., equation of state or number of secondary collisions). Our measurements of the quadrupole and non-quadrupole components have implications for the contributions to v2. They suggest that the main source of the difference between v2 \2\ and v2 \4\ (or v2 \2D\) is measured properties of minijets.