Non-Abelian Bremsstrahlung and Azimuthal Asymmetries in High Energy p+A Reactions

Abstract

We apply the GLV reaction operator solution to the Vitev-Gunion-Bertsch (VGB) boundary conditions to compute the all-order in nuclear opacity non-abelian gluon bremsstrahlung of event-by-event fluctuating beam jets in nuclear collisions. We evaluate analytically azimuthal Fourier moments of single gluon, vnM\1\, and even number 2 gluon, vnM\2\ inclusive distributions in high energy p+A reactions as a function of harmonic n, %independent target recoil cluster number, M, and gluon number, 2, at RHIC and LHC. Multiple resolved clusters of recoiling target beam jets together with the projectile beam jet form Color Scintillation Antenna (CSA) arrays that lead to characteristic boost non-invariant trapezoidal rapidity distributions in asymmetric B+A nuclear collisions. The scaling of intrinsically azimuthally anisotropic and long range in η nature of the non-abelian leads to vn moments that are similar to results from hydrodynamic models, but due entirely to non-abelian wave interference phenomena sourced by the fluctuating CSA. Our analytic non-flow solutions are similar to recent numerical saturation model predictions but differ by predicting a simple power-law hierarchy of both even and odd vn without invoking kT factorization. A test of CSA mechanism is the predicted nearly linear η rapidity dependence of the vn(kT,η). Non-abelian beam jet may thus provide a simple analytic solution to Beam Energy Scan (BES) puzzle of the near s independence of vn(pT) moments observed down to 10 AGeV where large x valence quark beam jets dominate inelastic dynamics. Recoil from multiple independent CSA clusters could also provide a partial explanation for the unexpected similarity of vn in p(D)+A and non-central A+A at same dN/dη multiplicity as observed at RHIC and LHC.