We explore the in-medium properties of heavy-quarkonium states at finite baryochemical potential and finite transverse momentum based on a modern complex-valued potential model. Our starting point is a novel, rigorous derivation of the generalized Gauss law for in-medium quarkonium, combining the nonperturbative physics of the vacuum bound state with a weak coupling description of the medium degrees of freedom. Its relation to previous models in the literature is discussed. We show that our approach is able to reproduce the complex lattice QCD heavy quark potential even in the nonperturbative regime, using a single temperature dependent parameter, the Debye mass m D . After vetting the Gauss law potential with state-of-the-art lattice QCD data, we extend it to the regime of finite baryon density and finite velocity, currently inaccessible to first principles simulations. In-medium spectral functions computed from the Gauss law potential are subsequently used to estimate the ψ ′ / J / ψ ratio in heavy-ion collisions at different beam energies and transverse momenta. We find qualitative agreement with the predictions from the statistical model of hadronization for the s N N dependence and a mild dependence on the transverse momentum.
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机译:我们探讨了重型Quarkonium态的中型特性,在有限的曲线化学潜力和有限横向动力基于现代复合潜在模型。我们的出发点是一种新颖的严格推导,用于中中Quarkonium的广义高斯法,将真空结合状态的非触发物理与中等自由度的弱耦合描述相结合。讨论了与文献中以前的模型的关系。我们表明我们的方法能够使用单一温度依赖性参数来再现复杂的晶格QCD重型夸克电位,即使用单温依赖性参数。在用最先进的格子QCD数据审查高斯法律潜力之后,我们将其扩展到有限的Baryon密度和有限速度的制度,目前难以实现的第一个原则模拟。随后使用从高斯法律电位计算的中谱函数,以估计不同光束能量和横向动量的重离子碰撞中的ψ'/ j /∞比。我们发现与S n N依赖性的统计模型的预测和对横向动量的温和依赖性的定性协议。
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