Probing nuclear structure in relativistic p-O and O-O collisions at the LHC through the measurement of anisotropic flow coefficients

Abstract: RHIC and LHC plan to inject $^{16}\rm O$ nuclei with a focus to investigate collectivity and the origin of quark-gluon plasma signatures in small collision systems. $^{16}\rm O$ nuclei is known to possess clusters of $\alpha$-particles ($^{4}\rm He$) inside the nucleus. In this paper, we study the anisotropic flow coefficients such as elliptic flow ($v_2$) and triangular flow ($v_3$), which are sensitive to the nuclear geometry of colliding nuclei, for p-O and O-O collisions at $\sqrt{s_{\rm NN}}=9.61$ TeV and 7 TeV respectively. The study is performed employing a hybrid model encompassing IPGlasma + MUSIC + iSS + UrQMD. The results of the clustered nuclear geometry are compared with those of the Woods-Saxon nuclear profile. Both initial and final state anisotropies are explored. This study is thus one of its first kind, where the study of anisotropic flow coefficients for p-O and O-O collisions is presented using a hybrid hydrodynamics model. We find a small effect of $\alpha$-clustering in p-O, while a significant one for O-O collisions. It is also observed that the magnitude of the effect correlates with the size of the $^{4}$He.