Abstract
In the nucleus $^{48}$Ti, whose structure is essential in evaluating the half-life of the neutrinoless double-$\beta$ decay ($0\nu\beta\beta$) of $^{48}$Ca, the existence of the $\alpha$ cluster structure is shown for the first time. A unified description of scattering and structure is performed for the $\alpha$+$^{44}$Ca system. By using a global potential, which reproduces experimental $\alpha$+$^{44}$Ca scattering over a wide range of incident energies, $E_\alpha$=18 - 100 MeV, it is shown that the observed $\alpha$+$^{44}$Ca fusion excitation function at $E_\alpha$=9 -18 MeV is described well. The bump at $E_\alpha$=10.2 MeV is found to be due to a resonance which is a $7^-$ state of the higher nodal band with the $\alpha$+$^{44}$Ca cluster structure in $^{48}$Ti. The local potential $\alpha$+$^{44}$Ca cluster model locates the ground band of $^{48}$Ti in agreement with experiment and reproduces the enhanced $B(E2)$ values in the ground band well. This shows that collectivity due to $\alpha$ clustering in $^{48}$Ti should be taken into account in the evaluation of the nuclear matrix element in the $0\nu\beta\beta$ double-$\beta$ decay of $^{48}$Ca.
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