Possible Evidence for Neutral Color-Singlet q q Quark Matter from High-Energy Pb-Emulsion Collisions

Abstract

The invariant mass spectrum of e+e- pairs produced in high-energy Pb-emulsion collisions at 160 A GeV at CERN SPS exhibits a complex structure of many resonances resting on top of a broad enhancement at invariant masses below 50 MeV, with the prominent resonance at 19 1 MeV providing independent support for the hypothetical X17 particle. We show that this complex structure may be coherently described as signatures for the neutral color-singlet q q quark matter in both its deconfined and confined phases. That is, the broad enhancement may arise from thermal annihilation of QED(U(1))-deconfined quarks and antiquarks into e+e- pairs at the phase transition temperature Tc(QED), theoretically estimated to be 4.75 1.2 MeV from the transitional equilibrium condition. The observed 31 and 71 MeV resonances may correspond to the QED(U(1))-deconfined d d and u u Coulomb bound states near their quark rest masses, respectively, whereas the observed 19 1 MeV resonance may correspond to the QED(U(1))-confined isoscalar QED meson. The approximate agreement between the theoretical and the experimental spectrum suggests that both QED(U(1))-confined and QED(U(1))-deconfined neutral color-singlet q q quark matter may have been produced in these high-energy Pb-emulsion collisions. We propose future experiments to confirm or refute these findings.