Detailed analysis of the gluonic excitation in the three-quark system in lattice QCD
Abstract
We study the excited-state potential and the gluonic excitation in the static three-quark (3Q) system using SU(3) lattice QCD with 163× 32 at β=5.8 and 6.0 at the quenched level. For about 100 different patterns of spatially-fixed 3Q systems, we accurately extract the excited-state potential V 3Q e.s. together with the ground-state potential V 3Q g.s. by diagonalizing the QCD Hamiltonian in the presence of three quarks. The gluonic excitation energy E 3Q V 3Q e.s.-V 3Q g.s. is found to be about 1 GeV at the typical hadronic scale. This large gluonic-excitation energy is conjectured to give a physical reason of the success of the quark model for low-lying hadrons even without explicit gluonic modes. We investigate the functional form of E 3Q in terms of the 3Q location. The lattice data of E 3Q are relatively well reproduced by the ``inverse Mercedes Ansatz'' with the ``modified Y-type flux-tube length'', which indicates that the gluonic-excitation mode is realized as a complicated bulk excitation of the whole 3Q system.
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