N. Schunck, J. D. McDonnell, D. Higdon, J. Sarich, S. M. Wild
Published 2015-03-19Version 1
Nuclear density functional theory (DFT) is one of the main theoretical tools used to study the properties of heavy and superheavy elements, or to describe the structure of nuclei far from stability. While on-going efforts seek to better root nuclear DFT in the theory of nuclear forces [see Duguet et al., this issue], energy functionals remain semi-phenomenological constructions that depend on a set of parameters adjusted to experimental data in finite nuclei. In this paper, we review recent efforts to quantify the related uncertainties, and propagate them to model predictions. In particular, we cover the topics of parameter estimation for inverse problems, statistical analysis of model uncertainties and Bayesian inference methods. Illustrative examples are taken from the literature.
Comments: Proceedings of the "Second International Workshop on Perspectives on Nuclear Data for the Next Decade", 14-17 October 2014, Bruy\`eres-le-Ch\^atel, France
Uncertainty Quantification for Nuclear Density Functional Theory and Information Content of New Measurements
$β$ decay of even-A nuclei within the interacting boson model based on nuclear density functional theory
Open problems in nuclear density functional theory
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