9 research outputs found
Low energy behavior of astrophysical S factor in radiative captures to loosely bound final states
The low-energy behavior of the astrophysical S-factor for E1 direct radiative
captures a(p,gamma)b leading to loosely bound final states (b=a+p) is
investigated. We derive a first-order integral representation for S(E) and
focus on the properties around zero energy. We show that it is the competition
between various effects, namely the remnant Coulomb barrier, the initial and
final centrifugal barriers and the binding energy, that defines the behavior of
the S(E->0). Contrary to previous findings, we prove that S(E->0) is not
determined by the pole corresponding to the bound state. The derivative S'(0)
increases with the increase of the centrifugal barrier, while it decreases with
the charge of the target. For l_i=l_f+1 the increase of the binding energy of
the final nucleus increases the derivative S'(0) while for l_i=l_f-1 the
opposite effect is found. We make use of our findings to explain the low energy
behavior of the S-factors related to some notorious capture reactions: 7Be(p,
gamma)8B, 14N(p,gamma)15O, 16O}(p,gamma)17F, 20Ne(p, gamma)21Na and 22Mg(p,
gamma)23Al.Comment: 30 pages, TeX (or Latex, etc). Nucl. Phys. A (in press