High energy QCD: multiplicity distribution and entanglement entropy

Abstract

In this paper we show that QCD at high energies leads to the multiplicity distribution σnσ in\,\,=\,\,1N\, N\,-\,1Nn - 1, (where N denotes the average number of particles), and to entanglement entropy S \,=\, N, confirming that the partonic stat at high energy is maximally entangled. However, the value of N depends on the kinematics of the parton cascade. In particular, for DISN = xG(x,Q) , where xG is the gluon structure function, whil for hadron-hadron collisions, N Q2S(Y), where Qs denotes the saturation scale. We checked that this multiplicity distribution describes the LHC data for low multiplicities n \,<\,(3 5)\,N, exceeding it for larger values of n. We view this as a result of our assumption, that the system of partons in hadron-hadron collisions atc.m. rapidity Y=0 is dilute. We show that the data can be described at large multiplicities in the parton model, if we do not make this assumption.