Scanning the Quark-Gluon Plasma with Charmonium
Abstract
We suggest the variation of charmonium suppression with Feynman xF in heavy ion collisions as a novel and sensitive probe for the properties of the matter created in such reactions. In contrast to the proton-nucleus case where nuclear suppression is weakest at small xF, final state interactions with the comoving matter create a minimum at xF=0, which is especially deep and narrow if a quark-gluon plasma is formed. While a particularly strong effect is predicted at SPS, at the higher RHIC energy it overlaps with the expected sharp variation with xF of nuclear effects and needs comparison with proton-nucleus data. If thermal enhancement of J/ production takes over at the energies of RHIC and LHC, it will form an easily identified peak, rather than dip in xF dependence. We predict a steep dependence on centrality and suggest that this new probe is complementary to the dependence on transverse energy, and is more sensitive to a scenario of final state interactions.
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