Signatures of α clustering in 16O by using a multiphase transport model

Abstract

α-clustered structures in light nuclei could be studied through "snapshots" taken by relativistic heavy-ion collisions. A multiphase transport (AMPT) model is employed to simulate the initial structure of collision nuclei and the proceeding collisions at center of mass energy sNN = 6.37 TeV. This initial structure can finally be reflected in the subsequent observations, such as elliptic flow (v2), triangular flow (v3) and quadrangular flow (v4). Three sets of the collision systems are chosen to illustrate system scan is a good way to identify the exotic α-clustered nuclear structure, case I: 16O nucleus (with or without α-cluster) + ordinary nuclei (always in Woods-Saxon distribution) in most central collisions, case II: 16O nucleus (with or without α-cluster) + 197Au nucleus collisions for centrality dependence, and case III: symmetric collision systems (namely, 10B + 10B, 12C + 12C, 16O + 16O (with or without α-cluster), 20Ne + 20Ne, and 40Ca + 40Ca) in most central collisions. Our calculations propose that relativistic heavy-ion collision experiments at sNN = 6.37 TeV are promised to distinguish the tetrahedron structure of 16O from the Woods-Saxon one and shed lights on the system scan projects in experiments.