Observable signatures of initial state momentum anisotropies in nuclear collisions

Abstract

We show that the correlation between the elliptic momentum anisotropy, v2, and the average transverse momentum, [pT], at fixed multiplicity in small system nuclear collisions carries information on the origin of the observed momentum anisotropy. A calculation using a hybrid IP-Glasma+Music+UrQMD model that includes contributions from final state response to the initial geometry as well as initial state momentum anisotropies of the Color Glass Condensate, predicts a characteristic sign change of the correlator (v22,[pT]) as a function of charged particle multiplicity in p+Au and d+Au collisions at s=200\, GeV, and p+Pb collisions at s=5.02\, TeV. This sign change is absent in calculations without initial state momentum anisotropies. The model further predicts a qualitative difference between the centrality dependence of (v22,[pT]) in Au+Au collisions at s=200\, GeV and Pb+Pb collisions at s=5.02\, TeV, with only the latter showing a sign change in peripheral events. Predictions for O+O collisions at different collision energy show a similar behavior. Experimental observation of these distinct qualitative features of (v22,[pT]) in small and large systems would constitute strong evidence for the presence and importance of initial state momentum anisotropies predicted by the Color Glass Condensate effective theory.