Collective string interactions in AdS/QCD and high multiplicity pA collisions

QCD strings originate from high-energy scattering in the form of Reggeons and Pomerons, and have been studied in some detail in lattice numerical simulations. Production of multiple strings, with their subsequent breaking, is now a mainstream model of high-energy pp and pA collisions. Recent LHC experiments revealed that the high multiplicity ends of such collisions show interesting collective effects. This ignited an interest in the interaction of QCD strings and multistring dynamics. Holographic models, collectively known as AdS/QCD, developed in the last decade, describe both hadronic spectroscopy and basic thermodynamics, but so far no studies of the QCD strings have been done in this context. The subject of this paper is to do this. First, we study in more detail the scalar sector of hadronic spectroscopy, identifying "glueballs" and "scalar mesons," and calculate the degree of their mixing. The QCD strings, holographic images of the fundamental strings, thus have a "gluonic core" and a "sigma cloud." The latter generates σ exchanges and collectivization of the strings, affecting, at a certain density, the chiral condensate and even the minimum of the effective string potential, responsible for the very existence of the QCD strings. Finally, we run dynamical simulations of the multistring systems, in the "spaghetti" setting approximating central pA collisions, and specify conditions for their collectivization into a black hole, or the dual quark gluon plasma fireball.