Ground-state baryon masses in an equally mixed scalar-vector linear potential model
Physical review. D. Particles, fields, gravitation, and cosmology/Physical review. D. Particles and fields1997Vol. 55(1), pp. 291–298
Citations Over TimeTop 13% of 1997 papers
Abstract
Taking into account the pionic self-energy of the baryons, the color-electrostatic and magnetostatic energies due to one-gluon exchange, and the corrections due to the center-of-mass motion, the ground-state masses of the octet baryons are calculated in a chiral symmetric potential model of independent quarks. The effective potential representing phenomenologically the nonperturbative gluon interactions, including gluon self-couplings, is chosen with equally mixed scalar and vector parts in a linear form. The physical masses of the baryons so obtained with the strong coupling constant \ensuremath{\alpha}${}_{c}$=0.576 agree very well with the corresponding experimental values.
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