The role of intermediate $\Delta\Delta$ states in nucleon-nucleon scattering in the large-$N_c$ and unitary limits, and $\Delta\Delta$ and $\Omega\Omega$ scattering

TL;DR

This paper investigates the influence of intermediate $\Delta\Delta$ states on nucleon-nucleon scattering within large-$N_c$ and unitary limits, revealing conditions under which $\Delta\Delta$ effects are perturbative or negligible, and extends analysis to $\Omega\Omega$ interactions.

Contribution

It provides a detailed analysis of baryon-baryon interactions including $\Delta\Delta$ states in large-$N_c$ effective field theory and explores symmetry enhancements in the unitary limit, extending to three-flavor systems.

Findings

Large-$N_c$ scaling relations hold for $S$-wave interactions regardless of $\Delta$ inclusion.

Higher partial waves with no mixing are perturbatively affected by $\Delta$ states.

In the unitary limit, one SU($2F$) parameter vanishes, indicating enhanced symmetries.

Abstract

We explore potential explanations for why using large-$N_c$ ($N_c$ is the number of colors) scaling to determine the relative size of few-nucleon low-energy operators agrees with experiment even when dynamical $\Delta$'s are not explicitly included. Given that the large-$N_c$ analysis is predicated on the nucleons and $\Delta$'s being degenerate, this is a curious result. We show that for purely $S$-wave interactions the relationships dictated by large-$N_c$ scaling are unaffected whether the $\Delta$ is included or not. In the case of higher partial waves that do not mix with $S$-waves, the impact of the $\Delta$ is perturbative, which makes the agreement with naive ($\Delta$-less) large-$N_c$ ordering unsurprising. For higher partial waves that mix with $S$-waves, the nucleon and $\Delta$ would need to decouple to get agreement with naive large-$N_c$ ordering. We find all $NN$, $\Delta N$, and $\Delta\Delta$ low energy coefficients for leading-order baryon-baryon scattering in $\Delta$-full pionless effective field theory in terms of the two independent parameters dictated by the SU($2F$) spin-flavor symmetry that arises in the $N_c \rightarrow \infty$ limit. Because of recent lattice QCD results and experimental interest, we extend our analysis to the three-flavor case to study $\Omega\Omega$ scattering. We show that in the unitary limit (where scattering lengths become infinite) one of the two SU($2F$) parameters is driven to zero, resulting in enhanced symmetries, which agree with those found in spin-1/2 entanglement studies.