Scalar-Quark Systems and Chimera Hadrons in SU(3)c Lattice QCD
Abstract
Light scalar-quarks φ (colored scalar particles or idealized diquarks) and their color-singlet hadronic states are studied with quenched SU(3)c lattice QCD in terms of mass generation in strong interaction without chiral symmetry breaking. We investigate ``scalar-quark mesons'' φ φ and ``scalar-quark baryons'' φφφ which are the bound states of scalar-quarks φ. We also investigate the bound states of scalar-quarks φ and quarks , i.e., φ , φ and φφ, which we name ``chimera hadrons''. All the new-type hadrons including φ are found to have a large mass even for zero bare scalar-quark mass mφ=0 at a-1 1GeV. We find that the constituent scalar-quark and quark picture is satisfied for all the new-type hadrons. Namely, the mass of the new-type hadron composed of m φ's and n 's, Mmφ+n, satisfies Mmφ+n m Mφ +n M, where Mφ and M are the constituent scalar-quark and quark mass, respectively. Mφ at mφ=0 estimated from these new-type hadrons is 1.5-1.6GeV, which is larger than that of light quarks, M 400 MeV. Therefore, in the systems of scalar-quark hadrons and chimera hadrons, scalar-quarks acquire large mass due to large quantum corrections by gluons. Together with other evidences of mass generations of glueballs and charmonia, we conjecture that all colored particles generally acquire a large effective mass due to dressed gluon effects.
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