Shallow $T_{bc}$ states from an EFT analysis of $B^{(*)} \bar D^{(*)}$ scattering on the lattice

TL;DR

This paper develops an effective field theory framework to analyze lattice QCD results on $B^{(*)}ar D^{(*)}$ scattering, revealing shallow $T_{bc}$ states and predicting additional bound states consistent with heavy-quark spin symmetry.

Contribution

It introduces two complementary EFT approaches for coupled-channel $B^{(*)}ar D^{(*)}$ scattering, incorporating contact interactions and one-pion exchange, and predicts new shallow bound states near relevant thresholds.

Findings

Support for shallow bound states in $B^{(*)}ar D^{(*)}$ channels

Finite-volume spectra show near-degeneracy consistent with HQSS

Predictions of additional bound states near $B ar D^*$ and $B^* ar D^*$ thresholds

Abstract

We present an effective field theory (EFT) framework for coupled-channel $B^{(*)}\bar D^{(*)}$ scattering, applying it to recent lattice QCD results by Alexandrou et al. [Phys. Rev. Lett. 132, 151902 (2024)]. Two complementary EFT approaches are developed: (1) A low-energy theory near the $B \bar D$ ($J=0$) and $B^* \bar D$ ($J=1$) thresholds, where coupled-channel effects are integrated out; (2) A coupled-channel formulation, where all relevant momentum scales are treated as soft, incorporating contact interactions and one-pion exchange (OPE). Importantly, OPE contributes to the lowest channels only through off-diagonal transitions, thus resulting in the appearance of the left-hand cut from two-pion exchange. The two approaches yield mutually consistent results, supporting the existence of shallow bound states in both channels, in agreement with the lattice findings. The finite-volume spectra and extracted pole positions show a near-degeneracy in $J=0$ and $J=1$ channels, consistent with heavy-quark spin symmetry (HQSS). Using HQSS, we predict additional shallow bound states near the $B \bar{D}^*$ and $B^* \bar{D}^*$ thresholds, which are accessible to future lattice simulations. The effect of OPE on the finite volume spectra is found to be small, with only moderate impact on HQSS partners.