Searching for small droplets of hydrodynamic fluid in proton--proton collisions at the LHC

Abstract

In this paper, we investigate the hydrodynamic collectivity in high-multiplicity events of proton-proton collisions at s= 13 TeV, using iEBE-VISHNU hybrid model with three different initial conditions, namely, HIJING, super-MC and TRENTo. With properly tuned parameters, hydrodynamic simulations with each initial model give reasonable descriptions of the measured two-particle correlations, including the integrated and p T-differential flow for all charged and identified hadrons. However, the hydrodynamic simulations fail to describe the negative value of the four-particle cumulant c2v\4\ as measured in experiments. Further investigations show that the non-linear response between the elliptic flow v2 and the initial eccentricity 2 becomes significant in the small p-p systems. This leads to a large deviation from linear eccentricity scaling and generates additional flow fluctuations, which results in a positive c2v\4\ even with a negative c2\4\ from the initial state. We also presented the first hydrodynamic calculations of multi-particle mixed harmonic azimuthal correlations in p-p collisions, such as normalized asymmetric cumulant nacn\3\, normalized Symmetric-Cumulant, nsc2,3\4\ and nsc2,4\4\. Although many qualitative features are reproduced by the hydrodynamic simulations with chosen parameters, the measured negative nsc2,3\4\ cannot be reproduced. The failure of the description of negative c2\4\ and nsc2,3\4\ triggers the question on whether hydrodynamics with a fundamentally new initial state model could solve this puzzle, or hydrodynamics itself might not be the appreciated mechanism of the observed collectivity in p-p collisions at the LHC.