Abstract
Azimuthal dihadron correlations of charged particles have been measured in PbPb collisions at $ \sqrt{{{s_{NN }}}} $ = 2.76TeV by the CMS collaboration, using data from the 2011 LHC heavy-ion run. The data set includes a sample of ultra-central (0-0.2% centrality) PbPb events collected using a trigger based on total transverse energy in the hadron forward calorimeters and the total multiplicity of pixel clusters in the silicon pixel tracker. A total of about 1.8 million ultra-central events were recorded, corresponding to an integrated luminosity of 120 μb − 1. The observed correlations in ultra-central PbPb events are expected to be particularly sensitive to initial-state fluctuations. The single-particle anisotropy Fourier harmonics, from v 2 to v 6, are extracted as a function of particle transverse momentum. At higher transverse momentum, the v 2 harmonic becomes significantly smaller than the higher-order v n (n ≥ 3). The p T-averaged v 2 and v 3 are found to be equal within 2%, while higher-order v n decrease as n increases. The breakdown of factorization of dihadron correlations into single-particle azimuthal anisotropies is observed. This effect is found to be most prominent in the ultra-central PbPb collisions, where the initial-state fluctuations play a dominant role. A comparison of the factorization data to hydrodynamic predictions with event-by-event fluctuating initial conditions is also presented.
Highlights
Along the short axis of the lenticular region
The data set includes a sample of ultra-central (0–0.2% centrality) PbPb events collected using a trigger based on total transverse energy in the hadron forward calorimeters and the total multiplicity of pixel clusters in the silicon pixel tracker
Due to event-by-event fluctuations, higher-order deformations or eccentricities of the initial geometry can be induced, which lead to higher-order Fourier harmonics in the final state with respect to their corresponding event plane angles, Ψn [18,19,20,21,22,23,24]
Summary
Along the short axis of the lenticular region. the eccentricity of initial-state collision geometry results in an anisotropic azimuthal distribution of the final-state hadrons. Studies of azimuthal anisotropy in ultra-central heavy-ion collisions can help to reduce the systematic uncertainties of initial-state modeling in extracting the η/s value of the system, quantitative comparison to theoretical calculations is beyond the scope of this paper. Due to the effect of initial-state fluctuations, it was recently predicted by hydrodynamic models that a pT-dependence of the event plane angle will be induced, which could be one of the sources responsible for the breakdown of factorization in extracting vn harmonics from dihadron correlations [26, 27]. The ultra-central heavy-ion events are dominated by the initial-state eccentricity fluctuations They provide an ideal testing ground for the effect of a pT-dependent event plane angle. This study of factorization is quantitatively compared to hydrodynamic predictions with different models of initial-state fluctuations and η/s values for two centrality classes
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
