Full-Coupled Channel Approach to Doubly Strange s-Shell Hypernuclei
Abstract
We describe ab initio calculations of doubly strange, S=-2, s-shell hypernuclei (4H, 5H, 5He and 6He) as a first attempt to explore the few-body problem of the full-coupled channel scheme for these systems. The wave function includes , , N and channels. Minnesota NN, D2 YN, and simulated YY potentials based on the Nijmegen hard-core model, are used. Bound state solutions of these systems are obtained. We find that a set of phenomenological B8B8 interactions among the octet baryons in S=0, -1 and -2 sectors, which is consistent with all of the available experimental binding energies of S=0, -1 and -2 s-shell (hyper-)nuclei, can predict a particle stable bound state of 4H. For 5H and 5He, N- N and N- potentials enhance the net -N coupling, and a large probability is obtained even for a weaker -N potential.
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