Binding of antikaons and Lambda(1405) clusters in light kaonic nuclei

Abstract

The energy spectra of light-mass kaonic nuclei were investigated using the theoretical framework of the 0s-orbital model with zero-range K N and KK interactions of effective single-channel real potentials. The energies of the K NN, K NNN, K NNNN, KK N, and KK NN systems were calculated in the cases of weak- and deep-binding of the K N interaction, which was adjusted to fit the (1405) mass with the energy of the K N bound state. The results qualitatively reproduced the energy systematics of kaonic nuclei calculated via other theoretical approaches. In the energy spectra of the K NN and KK NN systems, the lowest states K NN(Jπ,T=0-,1/2) and KK NN(0+,0) were found to have binding energies approximately twice and four times as large as that of the K N(1/2-,0) state, respectively. Higher (Jπ,T) states including K NN(1-,1/2), KK NN(0+,1), and KK NN(1+,1) were predicted at energies of 9--25 MeV below the antikaon-decay threshold. The effective (1405)-(1405) interaction in the KK N N system was also investigated via a K N+K N-cluster model. Strong and weak (1405)-(1405) attractions were obtained in the Sπ=0+ and Sπ=1- channels, respectively. The (1405)-(1405) interaction in the KK NN system was compared with the effective d-d interaction in the NNNN$ system, and the properties of dimer-dimer interactions in hadron and nuclear systems were discussed.