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Auteurs principaux: Saito, Yukiya, Dillmann, Iris, Kruecken, Reiner, Mumpower, Matthew R., Surman, Rebecca
Format: Preprint
Publié: 2023
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Accès en ligne:https://arxiv.org/abs/2305.01782
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author Saito, Yukiya
Dillmann, Iris
Kruecken, Reiner
Mumpower, Matthew R.
Surman, Rebecca
author_facet Saito, Yukiya
Dillmann, Iris
Kruecken, Reiner
Mumpower, Matthew R.
Surman, Rebecca
contents Developments in the description of the masses of atomic nuclei have led to various nuclear mass models that provide predictions for masses across the whole chart of nuclides. These mass models play an important role in understanding the synthesis of heavy elements in the rapid neutron capture ($r$-) process. However, it is still a challenging task to estimate the size of uncertainty associated with the predictions of each mass model. In this work, a method to quantify the mass uncertainty using \textit{ensemble Bayesian model averaging} (EBMA) is introduced. This Bayesian method provides a natural way to perform model averaging, selection, calibration, and uncertainty quantification, by combining the mass models as a mixture of normal distributions, whose parameters are optimized against the experimental data, employing the Markov chain Monte Carlo (MCMC) method using the No-U-Turn sampler (NUTS). The average size of our best uncertainty estimates of neutron separation energies based on the AME2003 data is 0.48 MeV and covers 95% of new data in the AME2020. The uncertainty estimates can also be used to detect outliers with respect to the trend of experimental data and theoretical predictions.
format Preprint
id arxiv_https___arxiv_org_abs_2305_01782
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Uncertainty Quantification of Mass Models using Ensemble Bayesian Model Averaging
Saito, Yukiya
Dillmann, Iris
Kruecken, Reiner
Mumpower, Matthew R.
Surman, Rebecca
Nuclear Theory
Developments in the description of the masses of atomic nuclei have led to various nuclear mass models that provide predictions for masses across the whole chart of nuclides. These mass models play an important role in understanding the synthesis of heavy elements in the rapid neutron capture ($r$-) process. However, it is still a challenging task to estimate the size of uncertainty associated with the predictions of each mass model. In this work, a method to quantify the mass uncertainty using \textit{ensemble Bayesian model averaging} (EBMA) is introduced. This Bayesian method provides a natural way to perform model averaging, selection, calibration, and uncertainty quantification, by combining the mass models as a mixture of normal distributions, whose parameters are optimized against the experimental data, employing the Markov chain Monte Carlo (MCMC) method using the No-U-Turn sampler (NUTS). The average size of our best uncertainty estimates of neutron separation energies based on the AME2003 data is 0.48 MeV and covers 95% of new data in the AME2020. The uncertainty estimates can also be used to detect outliers with respect to the trend of experimental data and theoretical predictions.
title Uncertainty Quantification of Mass Models using Ensemble Bayesian Model Averaging
topic Nuclear Theory
url https://arxiv.org/abs/2305.01782