Abstract
In the heavy-quark limit, the two heavy quarks in a doubly heavy baryon or a doubly heavy tetraquark are bound by their color-Coulomb potential into a compact diquark. The doubly heavy hadrons are related by the approximate heavy-quark--diquark symmetry of QCD to the heavy hadrons obtained by replacing the heavy diquark by a heavy antiquark. Effective field theories can be used to expand the masses of singly heavy hadrons and doubly heavy hadrons in inverse powers of the heavy quark masses. The coefficients in the expansions for doubly heavy tetraquarks can be determined from those for heavy mesons, heavy baryons, and doubly heavy baryons using heavy-quark--diquark symmetry. We predict the masses of the ground-state doubly heavy tetraquarks with error bars using as inputs the masses of heavy mesons and heavy baryons measured in experiments and the masses of doubly heavy baryons calculated using lattice QCD. The only doubly heavy tetraquarks predicted to be stable with respect to strong decays are $bb$ tetraquarks with light flavor $\bar u \bar d$, $\bar s \bar u$ and $\bar s \bar d$.
Highlights
One of the most basic properties of a quantum field theory is its particle spectrum
We presented predictions for the masses of doubly heavy tetraquarks with error bars
Our analysis was based on the Hamiltonian for doubly heavy hadrons in Eq (8), which provides an expansion for their masses to first order in the inverse heavy-quark masses 1=mQ
Summary
One of the most basic properties of a quantum field theory is its particle spectrum. The stable particles are important, because they can exist as asymptotic states. Manohar and Wise pointed out that QCD predicts that there must be stable QQqq ̄ tetraquark mesons in the limit of infinite heavy-quark mass [3]. Bicudo et al used lattice QCD calculations of static potentials for two heavy quarks together with the Born-Oppenheimer approximation to present evidence for the existence of a stable tetraquark with flavor bbud ̄ [8,9]. We instead use the masses of doubly heavy baryons calculated using lattice QCD, which have well-defined error bars This allows us to give predictions for the masses of doubly heavy tetraquarks in the heavy-diquark limit with error bars. We use the masses of ground-state heavy baryons calculated using lattice QCD to determine coefficients in the expansions. IV by summarizing our results and discussing the prospects for more accurate predictions of the masses for doubly heavy tetraquarks
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