Correlation between nuclear isospin asymmetry and α-particle preformation probability for superheavy nuclei from a Bayesian inference
Abstract
In the study of α decay within the superheavy nuclear region (Z ≥ 90 and N ≥ 140), the α-particle preformation probability Pα serves as a crucial physical quantity linking nuclear structure to decay observables. We introduce a phenomenological model incorporating the decay energy Qα, mass number A, orbital angular momentum l, isospin asymmetry I, and unpaired nucleon effect. For the first time, a Bayesian inference method combined with Markov Chain Monte Carlo (MCMC) sampling has been employed to impose global constraints on the model parameters, enabling the systematic and high-precision calculation of Pα. The results reveal a significant suppressing effect of isospin asymmetry on Pα, a finding independently corroborated by random forest-based feature importance analysis, which identified I as a dominant factor. Furthermore, calculations using the maximum a posteriori (MAP) parameters not only reproduce the shell effect at N=152 but also yield α decay half-life predictions in excellent agreement with experimental ones, thereby validating this model universality. This work provides the first global analysis tool for probing the α preformation mechanism in superheavy nuclei, underscores the potential of the Bayesian framework for inverting complex nuclear physics problems, and establishes a reliable theoretical benchmark for guiding future experimental exploration of superheavy nuclei.
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