Nuclear cluster structure effect in 16O+16O collisions at the top RHIC energy
Abstract
Using the improved string-melting version of a Multi-Phase Transport model, we investigated the impact of nuclear geometry of 16O on anisotropic flows in O+O collisions at s NN = 200 GeV. To evaluate the influence of nuclear structure and potential alpha clustering, we implemented four candidate configurations: Woods-Saxon, tetrahedron, square, and Nuclear Lattice Effective Field Theory. Initial-state geometry is quantified via the eccentricity cumulant ratio 2\4\/2\2\, which provides a robust and evolution-independent measure sensitive to configuration differences. The model reproduces v2(p T) at low p T and v3(p T) across the full p T range, with integrated v2\2\ and v3\2\ matching the STAR data, demonstrating that transport dynamics captures the essential collectivity in this intermediate-size system. These findings establish a baseline for extending nuclear-structure studies in O+O collisions to other energies and differential observables within a unified transport model framework.
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