A Mathematica script for harmonic oscillator nuclear matrix elements arising in semileptonic electroweak interactions

TL;DR

This paper introduces a Mathematica script that automates the calculation of harmonic oscillator nuclear matrix elements for semi-leptonic electroweak interactions, simplifying and error-proofing complex nuclear physics computations.

Contribution

The authors provide a novel Mathematica tool that automates the derivation of harmonic oscillator matrix elements for nuclear multipole operators, enhancing accuracy and efficiency.

Findings

Automated calculation of matrix elements reduces errors.

Script accelerates computation of neutrino scattering cross sections.

Application demonstrated on ^12C neutrino interactions.

Abstract

Semi-leptonic electroweak interactions in nuclei - such as \beta decay, \mu capture, charged- and neutral-current neutrino reactions, and electron scattering - are described by a set of multipole operators carrying definite parity and angular momentum, obtained by projection from the underlying nuclear charge and three-current operators. If these nuclear operators are approximated by their one-body forms and expanded in the nucleon velocity through order |\vec{p}|/M, where \vec{p} and M are the nucleon momentum and mass, a set of seven multipole operators is obtained. Nuclear structure calculations are often performed in a basis of Slater determinants formed from harmonic oscillator orbitals, a choice that allows translational invariance to be preserved. Harmonic-oscillator single-particle matrix elements of the multipole operators can be evaluated analytically and expressed in terms of finite polynomials in q^2, where q is the magnitude of the three-momentum transfer. While results for such matrix elements are available in tabular form, with certain restriction on quantum numbers, the task of determining the analytic form of a response function can still be quite tedious, requiring the folding of the tabulated matrix elements with the nuclear density matrix, and subsequent algebra to evaluate products of operators. Here we provide a Mathematica script for generating these matrix elements, which will allow users to carry out all such calculations by symbolic manipulation. This will eliminate the errors that may accompany hand calculations and speed the calculation of electroweak nuclear cross sections and rates. We illustrate the use of the new script by calculating the cross sections for charged- and neutral-current neutrino scattering in ^{12}C.