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More and more halo nuclei or candidates have been identified or suggested in experiments in recent years. It was declared that the halo structure of ^22Al is revealed by the large isospin asymmetry in ^22Si/^22O mirror Gamow-Teller transitions Phys. Rev. Lett. 125, 192503 (2020). We highlight that a significant mirror asymmetry already exists between wave functions of the likely unbound nucleus ^22Si and the doubly-magic nucleus ^22O, which largely explains the observed asymmetry in the transitions. Furthermore, these transitions involve only the 1^+ excited states of the daughter nuclei ^22Al and ^22F. The 1^+ state of ^22Al cannot be considered a halo state due to its proton-unbound nature. An analysis of the spin-parity suggests that a weakly bound 2s₁/₂ valence proton in the ground-state ^22Al is improbable. To investigate the shell structure for the ground state of ^22Al, we employ the state-of-the-art deformed and triaxial relativistic Hartree-Bogoliubov theories in continuum. We find that a small s-wave component of 5\% appears for the weakly bound valence proton in ^22Al only when triaxial deformation is considered. While the examination of densities and rms radii indicates that this small s-wave component is insufficient to form a discernible proton halo in ^22Al, slightly larger 2s₁/₂ occupations have been reported in other recent theoretical results. The question of how many low- components are sufficient to form a proton halo in the presence of the Coulomb barrier remains open. Thus, future measurements of reaction or interaction cross sections and momentum distributions of breakup fragments are highly desirable to verify whether ^22Al is a halo nucleus.
Zhang et al. (Thu,) studied this question.
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