Bayesian model averaging for nuclear symmetry energy from effective proton-neutron chemical potential difference of neutron-rich nuclei
Abstract
The data-driven Bayesian model averaging is a rigorous statistical approach to combining multiple models for a unified prediction. Compared with the individual model, it provides more reliable information, especially for problems involving apparent model dependence. In this work, within both the non-relativistic Skyrme energy density functional and the nonlinear relativistic mean field model, the effective proton-neutron chemical potential difference μ*pn of neutron-rich nuclei is found to be strongly sensitive to the symmetry energy Esym() around 20/3, with 0 being the nuclear saturation density. Given discrepancies on the μ*pn-Esym(20/3) correlations between the two models, we carry out a Bayesian model averaging analysis based on Gaussian process emulators to extract the symmetry energy around 20/3 from the measured μ*pn of 5 doubly magic nuclei 48Ca, 68Ni, 88Sr, 132Sn and 208Pb. Specifically, the Esym(20/3) is inferred to be Esym(20/3) = 25.6-1.3+1.4\,MeV at 1σ confidence level. The obtained constraints on the Esym() around 20/3 agree well with microscopic predictions and results from other isovector indicators.
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