Nonflow Subtraction Beyond Two-Particle Correlations

Abstract

Establishing collective flow in small collision systems is crucial for pinning down the minimum conditions for quark-gluon plasma (QGP) formation. In two-particle correlations, nonflow has been subtracted with good control, pushing the reach of flow measurements down to very small particle multiplicities N. However, the multi-particle nature of collectivity has not been established in the same N regime, because the residual nonflow surviving the subevent procedure in multi-particle cumulants has never been quantified. We develop a general nonflow subtraction framework for m-particle cumulants, built around the approximate 1/Nm-1 scaling of nonflow in the independent-source picture. Correlators containing v1 serve as clean nonflow estimators, since the p T-integrated dipolar flow nearly vanishes. Using as a controlled nonflow-only environment, we test the subtraction for three target observables ( v22, v22δp T, and c2\4\) in O+O and d+Au at s NN = 5.36 TeV and 200 GeV. Most of the nonflow is removed, with residual fractions typically within 20--30% when converted to the two-particle level, though the best estimator differs across the three targets. We identify a multiplicity-reweighting correction, previously overlooked in two-particle correlations, that explains the long-standing undersubtraction of the naive 1/N-scaling method; its impact grows as a power of the correlator order. The framework gives a systematic route to nonflow subtraction beyond two-particle correlations, broadening the class of multi-particle observables accessible to the small-system flow program.