Bound isoscalar axial-vector bc u d tetraquark Tbc from lattice QCD using two-meson and diquark-antidiquark variational basis

Abstract

We report a lattice QCD study of the heavy-light meson-meson interactions with an explicitly exotic flavor content bc u d, isospin I\!=\!0, and axialvector JP=1+ quantum numbers in search of possible tetraquark bound states. The calculation is performed at four values of lattice spacing, ranging 0.058 to 0.12 fm, and at five different values of valence light quark mass mu/d, corresponding to pseudoscalar meson mass Mps of about 0.5, 0.6, 0.7, 1.0, and 3.0 GeV. The energy eigenvalues in the finite-volume are determined through a variational procedure applied to correlation matrices built out of two-meson interpolating operators as well as diquark-antidiquark operators. The continuum limit estimates for D B* elastic S-wave scattering amplitude are extracted from the lowest finite-volume eigenenergies, corresponding to the ground states, using amplitude parametrizations supplemented by a lattice spacing dependence. Light quark mass mu/d dependence of the D B* scattering length (a0) suggests that at the physical pion mass a0phys = +0.57(+4-5)(17) fm, which clearly points to an attractive interaction between the D and B* mesons that is strong enough to host a real bound state Tbc, with a binding energy of -43(-7+6)(-24+14) MeV with respect to the D B* threshold. We also find that the strength of the binding decreases with increasing mu/d and the system becomes unbound at a critical light quark mass m*u/d corresponding to M*ps = 2.73(21)(19) GeV.