Abstract
We calculate masses of light and heavy mesons as well as baryons of negative parity containing $u,d,s,c$ and $b$ quarks. It is an extension of our previous work where we had studied the positive parity baryons. We adopt a quark-diquark picture of baryons where the diquarks are non-pointlike with a finite spatial extension. The mathematical foundation for this analysis is implemented through a symmetry-preserving Schwinger-Dyson equations treatment of a vector-vector contact interaction, which preserves key features of quantum chromodynamics, such as confinement, chiral symmetry breaking, axial vector Ward-Takahashi identity and low-energy Goldberger-Treiman relations. This treatment simultaneously describes mesons and provides attractive correlations for diquarks in the $\overline{3}$ representation. Employing this model, we compute the spectrum and masses of all spin-1/2 and spin-3/2 baryons of negative parity, supplementing our earlier evaluation of positive parity baryons, containing 1, 2 or 3 heavy quarks. In the process, we calculate masses of a multitude of mesons and corresponding diquarks. Wherever possible, we make comparisons of our results with known experimental observations as well as theoretical predictions of several models and approaches including lattice quantum chromodynamics, finding satisfactory agreement. We also make predictions for heavier states not yet observed in the experiment.
Highlights
The heavy baryons are an immediate prediction of the quark model and their spectroscopy has attracted a lot of attention in recent years due to their ongoing and expected observations in particle colliders such as LHCb and Belle II
The mathematical foundation for this analysis is implemented through a symmetry-preserving Schwinger-Dyson equations treatment of a vector-vector contact interaction, which preserves key features of quantum chromodynamics, such as confinement, chiral symmetry breaking, axial vector WardTakahashi identity, and low-energy Goldberger-Treiman relations
II we summarize the main features of the contact interaction (CI) along with the sets of parameters we shall employ in our subsequent analysis
Summary
We set out to calculate the masses of negative parity baryons of spin-1=2 and spin-3=2 These are parity partners of the baryons we studied in Ref. A similar amount of mass splitting is observed between the parity partners Δ3=2þð1232 MeVÞ and Δ3=2−ð1700 MeVÞ, as well as the nucleon N1=2þ ð939 MeVÞ and NÃ1=2−ð1535Þ This splitting is due to the effects of the DCSB-dictated repulsion involving P-wave components of the bound-state wave functions, incorporated in the kernels of the BSE and FE for the negative-parity hadrons. [9] to calculate the masses of negativeparity baryons by employing solutions of the BSE and the FE It naturally requires the study of axial and scalar mesons as well their corresponding diquarks.
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