Studying the QCD Matter produced in Heavy-Ion Collisions using the MUSES Calculation Engine

Abstract

The equation of state of hot and dense matter is essential for describing heavy-ion collisions at all collision energies. Here, we explore the capabilities of the latest version of the MUSES Calculation Engine, Calliope, focusing on software modules and workflows that compute the equation of state and observable properties of the matter produced in heavy-ion collisions. These include several equations of state, ranging from first-principles lattice QCD to phenomenological approaches, with or without a critical point, and with phase-space dimensionality ranging from two dimensions defined by temperature T and baryon chemical potential μB, to four dimensions after the addition of strangeness and electric-charge chemical potentials μS and μQ. We also discuss modules that provide additional thermodynamic quantities and observables relevant for heavy-ion modeling, including elements of the pressure Hessian matrix and transport coefficients. Workflow examples are constructed that merge two equations of state thermodynamically consistently to extend phase-diagram coverage, and feed the results into an equation of state inverter to produce inputs suitable for hydrodynamic simulations. Finally, we apply this framework to perform a relativistic viscous hydrodynamic simulation with equations of state with an extended T and μB coverage and a movable critical point, including effects from transport coefficients that phenomenologically encode critical scaling, at collision energies sNN=7.7, 19.6, and 39 GeV.