We study microscopic structures of monopole pair vibrational modes and associated two-neutron transfer amplitudes in neutron-rich Sn isotopes by means of the linear response formalism of the quasiparticle random phase approximation (QRPA). For this purpose we introduce a method to decompose the transfer amplitudes with respect to two-quasiparticle components of the QRPA eigenmode. It is found that pair-addition vibrational modes in neutron-rich ${}^{132–140}$Sn and the pair rotational modes in ${}^{142–150}$Sn are commonly characterized by coherent contribution of quasaiparticle states having high orbital angular momenta $l\gtrsim 5$, which suggests transfer of a spatially correlated neutron pair. The calculation also predicts a high-lying pair vibration, the giant pair vibration, emerging near the one-neutron separation energy in ${}^{110–130}$Sn, and we find that they have the same di-neutron characters as that of the low-lying pair vibration in ${}^{132–140}$Sn.

• Received 2 August 2013

DOI:https://doi.org/10.1103/PhysRevC.88.054308