Quantifying uncertainties in α-nucleus reaction dynamics informed from first principles

Authors

Kevin S. Becker, Louisiana State University
Aidan W. Kelly, Eberly College of Science
Kristina D. Launey, Louisiana State University
Scott T. Marley, Louisiana State University
Alexis Mercenne, Louisiana State University
Adriana R. Baniecki, University of Notre Dame
Tomáš Dytrych, Nuclear Physics Institute of the Academy of Sciences of the Czech Republic v. v. i.
Jerry P. Draayer, Louisiana State University

Document Type

Article

Publication Date

12-1-2025

Abstract

The ab initio symmetry-adapted no-core shell model is a microscopic many-body method which naturally describes challenging collective and clustering features of atomic nuclei. Wave functions and observables computed with realistic nucleon-nucleon forces in this framework are tied to first principles, and are hence well-suited for rigorous uncertainty quantification. We discuss α-deuteron and α-¹²C cluster potentials informed by symmetry-adapted calculations, and propagate uncertainties in the effective binary cluster method as well as those in the nuclear interaction to reaction observables, namely scattering phase shifts, cross sections, partial widths and resonance energies. We find that the overall uncertainties are dominated by those originating in the underlying nuclear force, speaking to the need for tighter constraints on realistic nucleon-nucleon interactions.

Publication Source (Journal or Book title)

Nuclear Physics A

Recommended Citation

Becker, K., Kelly, A., Launey, K., Marley, S., Mercenne, A., Baniecki, A., Dytrych, T., & Draayer, J. (2025). Quantifying uncertainties in α-nucleus reaction dynamics informed from first principles. Nuclear Physics A, 1064 https://doi.org/10.1016/j.nuclphysa.2025.123203