Speaker
Description
Nuclear transport simulations are essential theoretical tools for exploring the properties of high-density nuclear matter. Numerous heavy-ion collision facilities around the world, such as RAON, RIKEN Nishina Center, and FRIB, are conducting a wide range of experiments, leading to the accumulation of extensive experimental data. In this context, the importance of nuclear transport simulations—capable of numerically describing the entire dynamical evolution of heavy-ion collisions from the initial non-equilibrium stage, through the high-density compression phase, to the final freeze-out stage—has become increasingly significant
In this talk, I will introduce the overall characteristics and theoretical framework of a nuclear transport model developed in Korea, along with its numerical implementation. I will also discuss various physical properties investigated using this model, including the equation of state of high-density nuclear matter, symmetry energy, collective flow, and particle production ratios.