Universality of Three Identical Bosons with Large, Negative Effective Range

Abstract

"Resummed-Range Effective Field Theory'' is a consistent nonrelativistic effective field theory of contact interactions with large scattering length a and an effective range r0 large in magnitude but negative. Its leading order is non-perturbative. Its observables are universal, i.e.~they depend only on the dimensionless ratio :=2r0/a, with the overall distance scale set by |r0|. In the two-body sector, the position of the two shallow S-wave poles in the complex plane is determined by . We investigate three identical bosons at leading order for a two-body system with one bound and one virtual state (0), or with two virtual states (0<1). Such conditions might, for example, be found in systems of heavy mesons. We find that no three-body interaction is needed to renormalise (and stabilise) Resummed-Range EFT at LO. A well-defined ground state exists for 0.366…-8.72…. Three-body excitations appear for even smaller ranges of around the ``quasi-unitarity point'' =0 (|r0||a|∞) and obey discrete scaling relations. We explore in detail the ground state and the lowest three excitations and parametrise their trajectories as function of and of the binding momentum 2- of the shallowest state from where three-body and two-body binding energies are identical to zero three-body binding. As |r0||a| becomes perturbative, this version turns into the ``Short-Range EFT'' which needs a stabilising three-body interaction and exhibits Efimov's Discrete Scale Invariance. By interpreting that EFT as a low-energy version of Resummed-Range EFT, we match spectra to determine Efimov's scale-breaking parameter * in a renormalisation scheme with a ``hard'' cutoff. Finally, we compare phase shifts for scattering a boson on the two-boson bound state with that of the equivalent Efimov system.