Measurement of the longitudinal flow-plane decorrelation using multi-plane cumulants in s_NN = 200 GeV Au+Au, Ru+Ru, and Zr+Zr collisions

Abstract

Measurements of the variation of anisotropic flow-plane angles (n) with rapidity, commonly known as the flow-plane decorrelation, provide important insights into the initial conditions of the matter produced in heavy-ion collisions. In this paper, using data collected by the STAR experiment, we report the first measurement of the four-plane correlator observable Tn\ba;dc\= [n(bn-an)][n(dn-cn)], where superscripts a, b, c, and d denote sequential pseudorapidity (η) regions with a corresponding to the most backward region, b and c close to mid-rapidity with ηb<0 and ηc>0, and d being the most forward. The measurement is performed for the elliptic and triangular flow (i.e. n=2 and 3) in Au+Au and isobar (Ru+Ru, Zr+Zr) collisions at s_NN = 200 GeV. The goal of calculating the correlation of the flow-plane angle variations from backward to mid-central, and from mid-central to forward regions, is to probe the systematic variation of flow angle over a wide η range. In mid-central collisions (10-30\% centrality), we find T2\ba;dc\= -0.004 0.001 ( stat)0.002( syst) independent of the collision system. Such a small value of T2 favors a ''random-walk'' variation of the flow-plane angles, where the rapidity correlation length is smaller than the entire region under study. These measurements provide new information on the decorrelation patterns in the system and offer a quantitative estimate of possible systematic variations in anisotropic flow angles such as ''twist'' between forward and backward regions. This opens new opportunities for understanding the three-dimensional structure and the time evolution of the quark-gluon plasma created in heavy-ion collisions.