Bottomonium suppression and elliptic flow from real-time quantum evolution

Abstract

We compute the suppression and elliptic flow of bottomonium using real-time solutions to the Schr\"odinger equation with a realistic in-medium complex-valued potential. To model the initial production, we assume that, in the limit of heavy quark masses, the wave-function can be described by a lattice-smeared (Gaussian) Dirac delta wave-function. The resulting final-state quantum-mechanical overlaps provide the survival probability of all bottomonium eigenstates. Our results are in good agreement with available data for RAA as a function of N part and pT collected at s NN = 5.02 TeV. In the case of v2 for the various states, we find that the path-length dependence of (1s) suppression results in quite small v2 for (1s). Our prediction for the integrated elliptic flow for (1s) in the 10-90% centrality class is v2[(1s)] = 0.0026 0.0007. We additionally find that, due to their increased suppression, excited bottomonium states have a larger elliptic flow and we make predictions for v2[(2s)] and v2[(3s)] as a function of centrality and transverse momentum. Similar to prior studies, we find that it is possible for bottomonium states to have negative v2 at low transverse momentum.