Application of a coupled-channel Complex Scaling Method with Feshbach projection to the K-pp system

Abstract

Kaonic nuclei (nuclear system with anti-kaons) have been an interesting subject in hadron and strange nuclear physics, because the strong attraction between anti-kaon and nucleon might bring exotic properties to that system. In this article, we investigate K-pp as a prototype of kaonic nuclei. Here, K-pp is a three-body resonant state in the KNN-π YN coupled channels. (Y=, ) To treat resonant states in a coupled-channel system properly, we propose newly a coupled-channel complex scaling method combined with the Feshbach projection (ccCSM+Feshbach method). In this method, the Feshbach projection is realized with help of so-called the extended closure relation held in the complex scaling method, and a complicated coupled-channel problem is reduced to a simple single-channel problem which one can treat easily. First, we confirm that the ccCSM+Feshbach method completely reproduces results of a full coupled-channel calculation in case of two-body KN-π Y system. We then proceed to study of three-body KNN-π YN system, and successfully find solutions of the K-pp resonance by imposing self-consistency for the complex KN energy. Obtained binding energy of K-pp is well converged around 27 MeV, with an energy-dependent KN(-π Y) potential based on the chiral SU(3) theory, independently of ansatz for the self-consistency. This binding energy is small as ones reported in earlier studies based on chiral models. The decay width of K-pp strongly depends on the ansatz. We calculate also the correlation density of NN and KN pairs by using the obtained complex-scaled wave function of the K-pp resonance. Effect of the repulsive core of NN potential and survival of * resonance are confirmed.