Radii in the sd shell and the s1/2 "halo" orbit: A game changer

Abstract

Proton radii of nuclei in the sd shell depart appreciably from the asymptotic law, π=0A1/3. The departure exhibits systematic trends fairly well described by a single phenomenological term in the Duflo-Zuker formulation, which also happens to explain the sudden increase in slope in the isotope shifts of several chains at neutron number N=28. It was recently shown that this term is associated with the abnormally large size of the s1/2 and p orbits in the sd and pf shells respectively. Further to explore the problem, we propose to calculate microscopically radii in the former. Since the (square) radius is basically a one body operator, its evolution is dictated by single particle occupancies determined by shell model calculations. Assuming that the departure from the asymptotic form is entirely due to the s1/2 orbit, the expectation value s1/2|r2|s1/2 is determined by demanding that its evolution be such as to describe well nuclear radii. It does, for an orbit that remains very large (about 1.6 fm bigger than its d counterparts) up to N,\,Z=14 then drops abruptly but remains some 0.6 fm larger than the d orbits. An unexpected behavior bound to challenge our understanding of shell formation.