The anatomy of atomic nuclei: illuminating many-body wave functions through group-theoretical decomposition

TL;DR

This paper explores how group-theoretical decomposition of nuclear many-body wave functions reveals underlying patterns and symmetries, supporting the use of symmetry-based frameworks in nuclear physics.

Contribution

It demonstrates that group decompositions can effectively characterize complex nuclear wave functions, revealing shared intrinsic shapes and similarities across different force models.

Findings

Group decompositions show coherent patterns along rotational bands.

Decompositions from phenomenological and extit{ab initio} forces are very similar.

Group-theoretical analysis supports symmetry-based approaches in nuclear physics.

Abstract

With modern computers we can compute nuclear many-body wave functions with an astounding number of component, $ > 10^{10}$. But, aside from reproducing and/or predicting experiments, what do we learn from vectors with tens of billions of components? One way to characterize wavefunctions is through irreducible representations of groups. I discuss briefly the history of group-theoretical characterization of nuclear wavefunctions, with an emphasis of using Lanczos-type methods to efficiently dissect arbitrary wavefunctions into group irreps. Although the resulting decompositions are often fragmented over many irreps, one nonetheless finds powerful patterns. First, group decompositions along rotational bands show coherent commonalities, supporting the picture of a shared "intrinsic shape;" this is also called \textit{quasi-dynamical symmetry}. Second, group decompositions for wave functions using both phenomenological and \textit{ab initio} forces are often very similar, despite vastly different origins and dimensionalities. Both of these results suggest a group theoretical decomposition can provide a robust "anatomy" of many nuclear wave functions. This in turn supports the idea of using symmetry-based many-body frameworks for calculations.