Isospin Properties of (K-, N) Reactions for the Formation of Deeply-bound Antikaonic Nuclei

Abstract

The formation of deeply-bound antikaonic K-/K0 nuclear states by nuclear (K-, N) reactions is investigated theoretically within a distorted-wave impulse approximation (DWIA), considering the isospin properties of the Fermi-averaged K-+ N N + K elementary amplitudes. We calculate the formation cross sections of the deeply-bound K states by the (K-, N) reactions on the nuclear targets, 12C and 28Si, at incident K- lab momentum pK- = 1.0 GeV/c and θ lab = 0, introducing a complex effective nucleon number N eff for unstable bound states in the DWIA. The results show that the deeply-bound K states can be populated dominantly by the (K-, n) reaction via the total isoscalar T=0 transition owing to the isospin nature of the K-+ N N + K amplitudes, and that the cross sections described by ReN eff and ArgN eff enable to deduce the structure of the K nuclear states; the calculated inclusive nucleon spectra for a deep K-nucleus potential do not show distinct peak structure in the bound region. The few-body K [NN] and K [NNN] states formed in (K-, N) reactions on s-shell nuclear targets, 3He, 3H and 4He, are also discussed.