Tomography of high-energy nuclear collisions with photon-hadron correlations

Abstract

Within the next-to-leading order (NLO) perturbative QCD (pQCD) parton model, suppression of away-side hadron spectra associated with a high pT photon due to parton energy loss is studied in high-energy heavy-ion collisions. Dictated by the shape of the γ-associated jet spectrum in NLO pQCD, hadron spectra at large zT=pTh/pTγ > 1 are more sensitive to parton energy loss and therefore are dominated by surface emission of γ-associated jets, whereas small zT hadrons mainly come from fragmentation of jets with reduced energy which is controlled by the volume emission. These lead to different centrality dependence of the γ-hadron suppression for different values of zT. Therefore, a complete measurement of the suppression of γ-triggered hadron spectra, including its dependence on the orientation of the γ-hadron pair with respect to the reaction plane, allows the extraction of the spatial distribution of jet quenching parameters, achieving a true tomographic study of the quark-gluon plasma in high-energy heavy-ion collisions.