QCD predicts the creation of Quark-Gluon Plasma (QGP) at extremely high energy densities. Composed of interacting quarks, antiquarks, and gluons, this state of matter is believed to have existed shortly after the Big Bang. Modern studies of QGP are conducted through ultra-relativistic heavy-ion collisions at facilities like RHIC at BNL and LHC at CERN.
The discovery of QGP in these experiments is now well-accepted, but understanding its properties remains challenging. Currently, QGP is viewed as a nearly perfect fluid, with its shear viscosity over entropy ratio (eta/s) approaching a conjectured universal lower bound. Interestingly, similar behavior is observed in ultracold Fermi gases, suggesting parallels between extremely hot and cold systems.
However, the portrayal of QGP as a nearly perfect fluid is under scrutiny. For most substances, eta/s reaches a minimum near the phase transition temperature (Tc), increasing with temperature rather than remaining constant. Studies, including hydrodynamics simulations, indicate that bulk medium simulations are not sensitive to substantial increases in eta/s near Tc, questioning the overly idealized perfect fluid notion.
Given that this perfect fluid picture emerges from low momentum data and hydrodynamic models, there's a need for independent datasets and theoretical predictions to refine our understanding of QGP. Our research proposes high-momentum (high-pt) parton data, compared with pQCD predictions, to explore QGP properties.