Measurement of q in RHI collisions using di-hadron correlations

Abstract

In the BDMPSZ model, the energy loss of an outgoing parton in a medium -dE/dx is the transport coefficient q times L the length traveled. This results in jet quenching, which is well established. However BDMPSZ also predicts an azimuthal broadening of di-jets also proportional to qL which has so far not been observed. The broadening should produce a larger kT in A+A than in p+p collisions. This presentation introduces the observation that the kT measured in p+p collisions for di-hadrons with pTt and pTa must be reduced to compensate for the energy loss of both the trigger and away parent partons when comparing to the kT measured with the same di-hadron pTt and pTa in A+A collisions. This idea is applied to a recent STAR di-hadron measurement in Au+Au at sNN=200 GeV, [Phys. Lett. B760 (2016) 689], with result <qL>=2.1 0.6 GeV2. This is more precise but in agreement with a theoretical calculation of <qL>=14+42-14 GeV2 using the same data. Assuming a length <L>≈ 7 fm for central Au+Au collisions the present result gives q≈ 0.30 0.09 GeV2/fm, in fair agreement with the JET collaboration result from single hadron suppression of q≈ 1.2 0.3 GeV2/fm at an initial time τ0=0.6 fm/c in Au+Au collisions at sNN=200 GeV. There are several interesting details to be discussed: for a given pTt the <qL> seems to decrease then vanish with increasing pTa; the di-jet spends a much longer time in the medium (≈ 7 fm/c) then τ0=0.6 fm/c which likely affects the value of q that would be observed.