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Model study on Upsilon(nS) modification in small collision systems

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arxiv 2209.12303 v1 pith:5P66XGZZ submitted 2022-09-25 nucl-th nucl-ex

Model study on Upsilon(nS) modification in small collision systems

classification nucl-th nucl-ex
keywords collisioncollisionssmallsystemsupsiloneffectsmodificationheavy-ion
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Quarkonium production has been studied extensively in relativistic heavy-ion collision experiments to understand the properties of the quark gluon plasma. The experimental results on the yield modification in heavy-ion collisions relative to that in $p$+$p$ collisions can be described by several models considering dissociation and regeneration effects. A yield modification beyond initial-state effects has also been observed in small collision systems such as $p$+Au and $p$+Pb collisions, but it is still premature to claim any hot medium effect. A model study in various small collision systems such as $p$+$p$, $p$+Pb, $p$+O, and O+O collisions will help quantitatively understanding nuclear effects on the $\Upsilon(nS)$ production. A theoretical calculation considering the gluo-dissociation and inelastic parton scattering and their inverse reaction reasonably describes the suppression of $\Upsilon(1S)$ in Pb+Pb collisions. Based on this calculation, a Monte-Carlo simulation is developed to more realistically incorporate the medium produced in heavy-ion collisions with event-by-event initial collision geometry and hydrodynamic evolution. We extend this framework to small systems to study the medium effects. In this work, we quantify the nuclear modification factor of $\Upsilon(nS)$ as a function of charged particle multiplicity ($dN_{ch}/d\eta$) and transverse momentum. We also calculate the elliptic flow of $\Upsilon(nS)$ in small collision systems.

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  1. A multi-differential constraint map for quarkonium suppression mechanisms in high-multiplicity pp and pPb collisions

    hep-ph 2026-06 unverdicted novelty 4.0

    Multi-differential constraint analysis of Υ(nS) suppression in high-multiplicity pp and pPb collisions favors an early, globally correlated, topology-sensitive mechanism over local-density or total-multiplicity control.