Role of Tensor Interaction as Salvation of Cluster Structure in $^{44}$Ti

TL;DR

This paper investigates how tensor interactions influence cluster structures in $^{44}$Ti, showing that tensor effects can preserve clustering despite spin-orbit interactions that tend to break it, leading to near-degenerate configurations.

Contribution

The study introduces an improved method to evaluate tensor effects within the cluster model, revealing their role in maintaining cluster structures in medium-heavy nuclei like $^{44}$Ti.

Findings

Tensor interactions help sustain alpha clustering in $^{44}$Ti.

Spin-orbit effects tend to break alpha clusters, restoring shell model symmetry.

Tensor and spin-orbit effects lead to nearly degenerate configurations in $^{44}$Ti.

Abstract

Background: The $^{44}$Ti nucleus has been known to have a $^{40}$Ca+$\alpha$ cluster structure, and inversion doublet structure has been observed; however, $\alpha$ cluster structure tends to be washed out when the breaking of the $\alpha$ cluster is allowed due to the spin-orbit interaction. Nevertheless, $\alpha$ clustering in medium-heavy nuclei is quite a hot subject recently. Purpose: The tensor interaction has been known to play an essential role in the strong binding of the $^4$He nucleus, which induces the two-particle-two-hole (2p2h) excitation. Since this excitation is blocked when another nucleus approaches, it is worthwhile to show whether the tensor effect works to keep the distance between $^4$He and $^{40}$Ca and becomes the salvation of the clustering in $^{44}$Ti. Methods: The spin-orbit effect is included in the cluster model by using the antisymmetrized quasi cluster model (AQCM) developed by the authors. We have also developed an improved version of the simplified method to include the tensor contribution ($i$SMT), which allows us to estimate the tensor effect within the cluster model. The competition of these two is investigated in the medium-heavy mass region for the first time. Results: According to AQCM, the spin-orbit interaction completely breaks the $\alpha$ cluster and restores the symmetry of $jj$-coupling shell model when the $\alpha$ cluster approaches the $^{40}$Ca core. On the other hand, $i$SMT gives a large distance between $\alpha$ and $^{40}$Ca due to the tensor effect. Conclusions: In $^{44}$Ti, because of the strong spin-orbit and tensor contributions, two completely different configurations ($jj$-coupling shell model and cluster states) almost degenerate, and their mixing becomes important.