Rescuing the nonjet (NJ) azimuth quadrupole from the flow narrative

TL;DR

This paper challenges the flow interpretation of the nonjet azimuth quadrupole in high-energy nuclear collisions, presenting evidence that it originates from a nonflow QCD mechanism with distinct spectral properties.

Contribution

It isolates quadrupole spectra from $v_2(p_t)$ data, revealing characteristics inconsistent with flow and supporting a nonflow QCD origin.

Findings

Quadrupole spectra differ from single-particle spectra for most hadrons.

A universal quadrupole spectrum describes multiple hadron species.

Quadrupole spectrum shape remains consistent from RHIC to LHC energies.

Abstract

According to the flow narrative commonly applied to high-energy nuclear collisions a cylindrical-quadrupole component of 1D azimuth angular correlations is conventionally denoted by quantity $v_2$ and interpreted to represent elliptic flow. Jet angular correlations may also contribute to $v_2$ data as "nonflow" depending on the method used to calculate $v_2$, but 2D graphical methods are available to insure accurate separation. The nonjet (NJ) quadrupole has various properties inconsistent with a flow interpretation, including the observation that NJ quadrupole centrality variation in A-A collisions has no relation to strongly-varying jet modification ("jet quenching") in those collisions commonly attributed to jet interaction with a flowing dense medium. In this presentation I describe isolation of quadrupole spectra from pt-differential $v_2(p_t)$ data from the RHIC and LHC. I demonstrate that quadrupole spectra have characteristics very different from the single-particle spectra for most hadrons, that quadrupole spectra indicate a common boosted hadron source for a small minority of hadrons that "carry" the NJ quadrupole structure, that the narrow source-boost distribution is characteristic of an expanding thin cylindrical shell (strongly contradicting hydro descriptions), and that in the boost frame a single universal quadrupole spectrum (L\'evy distribution) on transverse mass $m_t$ accurately describes data for several hadron species scaled according to their statistical-model abundances. The quadrupole spectrum shape changes very little from RHIC to LHC energies. Taken in combination those characteristics strongly suggest a unique {\em nonflow} (and nonjet) QCD mechanism for the NJ quadrupole conventionally represented by $v_2$.