Uncertainty quantification of collective nuclear observables from the chiral potential parametrization
Journal article, 2024
We perform an uncertainty estimate of quadrupole moments and B(E2) transition rates that inform nuclear collectivity. In particular, we study the low-lying states of 6Li and 12C using the ab initio symmetry-adapted no-core-shell model. For a narrow standard deviation of approximately 1% on the low-energy constants which parametrize high-precision chiral potentials, we find output standard deviations in the collective observables ranging from approximately 3%-6%. The results mark the first step towards a rigorous uncertainty quantification of collectivity in nuclei that aims to account for all sources of uncertainty in ab initio descriptions of challenging collective and clustering observables.
symmetry
nuclear collectivity
<italic>ab initio</italic>
uncertainty quantification
Author
Kevin S. Becker
Louisiana State University
Kristina D. Launey
Louisiana State University
Andreas Ekström
Chalmers, Physics, Subatomic, High Energy and Plasma Physics
Tomas Dytrych
Czech Academy of Sciences
Daniel Langr
Czech Technical University in Prague
Grigor H. Sargsyan
Michigan State University
Jerry P. Draayer
Louisiana State University
Physica Scripta
00318949 (ISSN) 14024896 (eISSN)
Vol. 99 12 125311The strong nuclear interaction: governing the quantum properties of nuclei and the neutron-star equation of state
Swedish Research Council (VR) (2020-05127), 2021-01-01 -- 2022-12-31.
Strong interactions for precision nuclear physics (PrecisionNuclei)
European Commission (EC) (EC/H2020/758027), 2018-02-01 -- 2023-01-31.
Subject Categories
Subatomic Physics
DOI
10.1088/1402-4896/ad8527