Investigation of the neutron-proton effective mass splitting via heavy ion collisions: Constraints and Implications
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The neutron-proton effective mass splitting ($\Delta m^*_{np}$) is investigated through analyses of heavy-ion collisions using the improved quantum molecular dynamics (ImQMD) model with both standard and extended Skyrme interactions. By uncovering the strong correlation between the slope of the neutron-to-proton yield ratio with respect to the kinetic energy (i.e., $S_{n/p} $) and $\Delta m^*_{np}$, we reveal that the constraints of the neutron-proton effective mass splitting via heavy ion collisions depend on the kinetic energy region of the emitted nucleons. At low kinetic energies, the data favor $m_n^*>m_p^*$ which is consistent with the nucleon-nucleus scattering analysis, while at high kinetic energies, they favor $m_n^*<m_p^*$. Our findings partly resolve the longstanding discrepancy in the constraints of neutron-proton effective mass splitting with heavy ion collisions and nucleon-nucleus scattering, and significantly advance the understanding of nucleon effective mass splitting through heavy ion collisions.
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Constraining neutron-proton effective mass splitting through nuclear giant dipole resonance within transport approach
Bayesian analysis of IVGDR properties in BUU transport simulations with Skyrme functionals constrains the neutron-proton effective mass splitting at saturation density to Δm*_1(ρ0)/m = 0.200 +0.101 -0.094.
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