Holographic imaginary potential of a quark antiquark pair in the presence of gluon condensation

Abstract

For a moving heavy quark antiquark (QQ) in a quark gluon plasma (QGP), we use gauge/gravity duality to study both real and imaginary parts of the potential (ReVQQ and ImVQQ respectively) in a gluon condensate (GC) theory. The complex potential is derived from the Wilson loop by considering the thermal fluctuations of the worldsheet of the Nambu-Goto holographic string. We calculate ReVQQ and ImVQQ in both cases where the axis of the moving QQ pair is transverse and parallel with respect to its direction of movement in the plasma. Using the renormalization scheme for the ReVQQ , we find that the inclusion of GC increases the dissociation length while rapidity has the opposite effect. While for the ImVQQ , we observe that by considering the effect of GC, the ImVQQ is generated for larger distance thus decreasing quarkonium dissociation, while rapidity has opposite effect. In particular, as the value of GC decreases in the deconfined phase, the ImVQQ is generated for smaller distance thus enhancing quarkonium dissociation, and at high temperatures it is nearly not modified by GC, consistent with previous findings of the entropic force.