M. C. Atkinson, K. Kravvaris, S. Quaglioni, P. Navrátil
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Ab initio calculation of the $^3$He$(α,γ)^7$Be astrophysical S factor with chiral two- and three-nucleon forces
The $^3$He$(\alpha,\gamma)^7$Be radiative capture reaction plays a key role
in the creation of elements in stars as well as in the production of solar
neutrinos, the observation of which is one of the main tools to study the
properties of our sun. Since accurate experimental measurements of this fusion
cross section at solar energies are difficult due to the strong Coulomb
repulsion between the reactants, the onus falls on theory to provide a robust
means for extrapolating from the region where experimental data is available
down to the desired astrophysical regime. We present the first microscopic
calculations of $^3$He$(\alpha,\gamma)^7$Be with explicit inclusion of
three-nucleon forces. Our prediction of the astrophysical $S$ factor
qualitatively agrees with experimental data. We further incorporate
experimental bound-state and scattering information in our calculation to
arrive at a more quantitative description. This process reveals that our
current model lacks sufficient repulsion in the $1/2^+$ channel of our model
space to simultaneously reproduce elastic-scattering data. This deficit
suggests that $^3$He$(\alpha,\gamma)^7$Be probes aspects of the nuclear force
that are not currently well-constrained.
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