Evolution of clustering structure through the momentum distributions in 8-10Be isotopes

Abstract

We investigate the evolution of clustering structure through the momentum distributions in the 8-10Be isotopes. The nucleon dynamics within the inter-cluster antisymmetrization are discussed via the momentum distribution of a Brink type α-α wave function. For the state with a small α-α distance, we observe a significant depression with a dip structure at zero-momentum and an enhanced tail at relatively higher momentum region. In addition, we find the "cluster structure" in the intrinsic frame of momentum space, which is complementary to its significant α-cluster dissolution in the coordinate space because of the strong antisymmetrization. For the physical 8-10Be isotopes, the Tohsaki-Horiuchi-Schuck-R\"opke (THSR) wave functions are adopted. The evolution from the dilute clustering state to the compact one is demonstrated by a successive depression at the zero-momentum of nucleon distribution for the two α-clusters within 8-10Be isotopes. For the compact 10Be nucleus, the momentum distribution of all nucleons shows significant depression at zero-momentum with a dip structure, which is found to be contributed by both the inter-cluster antisymmetrization and the p-orbit occupation of the valence neutrons. This study proposes a new window for the investigations of the α-clustering effects via the low-momentum components of nuclei, which is expected to be extended to the heavier nuclear clustering states.