Single-Particle Spin-Orbit Strengths of the Nucleon and Hyperons by SU6 Quark-Model
Abstract
The quark-model hyperon-nucleon interaction suggests an important antisymmetric spin-orbit component. It is generated from a color analogue of the Fermi-Breit interaction dominating in the one-gluon exchange process between quarks. We discuss the strength SB of the single-particle spin-orbit potential, following the Scheerbaum's prescription. Using the SU6 quark-model baryon-baryon interaction which was recently developed by the Kyoto-Niigata group, we calculate NN, Lambda N and Sigma N G-matrices in symmetric nuclear matter and apply them to estimate the strength SB. The ratio of SB to the nucleon strength SN =~ -40 MeV*fm5 is (SLambda)/(SN) =~ 1/5 and (SSigma)/(SN) =~ 1/2 in the Born approximation. The G-matrix calculation of the model FSS modifies SLambda to (SLambda)/(SN) =~ 1/12. For SN and SSigma, the effect of the short-range correlation is comparatively weak against meson-exchange potentials with a short-range repulsive core. The significant reduction of the Lambda single-particle potential arises from the combined effect of the antisymmetric LS force, the flavor-symmetry breaking originating from the strange to up-down quark-mass difference, as well as the effect of the short-range correlation. The density dependence of SB is also examined.
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