Investigation of -nn (S=-2) Hypernucleus in Low-energy Pionless Halo Effective Theory

Abstract

In the strangeness S=-2 sector, we study the -nn (I=3/2, JP=1/2+) three-body system using pionless halo effective field theory (EFT), which provides a systematic model independent framework for assessing the feasibility of light particle-stable three-body bound states, utilizing low-energy universality. Here we take recourse to a simplistic speculation of the three-body system by eliminating the repulsive spin-singlet - n sub-system, while retaining the predominantly attractive (possibly bound) spin-triplet -n and the virtual bound spin-singlet nn sub-system. In particular, a qualitative leading order EFT investigation by introducing a sharp momentum (ultraviolet) cut-off parameter c into the Faddeev-like coupled integral equations, indicates a discrete scaling behavior akin to a renormalization group limit cycle, thereby suggesting the formal existence of Efimov states in the unitary limit, as c ∞. Our subsequent non-asymptotic analysis indicates that the three-body binding energy B3 is sensitively dependent on the cut-off without the inclusion of three-body contact interactions. Furthermore, our analysis reproduces several values of the binding energy B3 3-4 MeV, predicted in context of existing potential models, with the regulator c in the range, 350-460 MeV. Finally, based on these model inputs for B3, a ballpark estimate of the three-body scattering length in the range, 2.6-4.9 fm, is naively constrained by our EFT analysis, ostensibly demonstrating the universal nature of three-body correlations that is likely to manifest themselves in a halo-bound -nn system.