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Abstract

Spin polarization provides a novel probe of the rotational properties of the quark-gluon plasma (QGP) formed in relativistic heavy-ion collisions. We investigate the effective transport and thermodynamic coefficients in non-central O+O collisions, employing a parton distribution function that incorporates spin polarization induced by thermal vorticity. Within a kinetic theory framework, we find that the magnitude of the squared speed of sound ($c_s^2$) is only weakly modified by spin polarization, whereas the specific shear viscosity ($\eta/s$), specific bulk viscosity ($\zeta/s$), and mean free path ($\lambda$) show substantial changes. When spin polarization is included, both $c_s^2$ and $\zeta/s$ develop a nonmonotonic dependence on the collision energy, with an inflection point near $\sqrt{s_{NN}}=27$ GeV, corresponding to an average parton chemical potential of $\langle\mu_p\rangle=0.021$ GeV. These results suggest that spin polarization may serve as a useful probe for constraining the effective equation of state of QCD matter.