The article explores the effects of a quark-gluon plasma medium on hadronization, focusing on a simplified event pipeline involving a single jet. The study observes how the proton-to-pion ratio changes with varying medium sizes and flow dynamics. With increasing brick lengths, the ratio indicates greater quark recombination. The presence of homogeneous longitudinal flow further shifts the peaks in the proton-to-pion ratios to higher momentum values. The effects of transverse flow are also investigated, demonstrating the complexity of interactions within the jet formation process in such media.
In our examination of the proton-to-pion ratio within a quark-gluon plasma, we find it notably increases with larger medium sizes, indicating enhanced quark recombination.
The introduction of a homogeneous longitudinal flow in jet direction significantly influences hadronization, as it shifts the proton-to-pion ratio peaks to higher momenta, evidencing momentum transfer from flowing thermal partons.
Thermal partons in the quark-gluon plasma play a crucial role in hadronization, and their interactions lead to observable changes in the particle ratios emerging from the medium.
By exploring both longitudinal and transverse flows, we gain insights into the dynamics of jet formation in a medium, underscoring the complexities of quark-gluon interactions.
Collection
[
|
...
]