Evaluation of the 35K(p,γ)36Ca reaction rate using the 37Ca(p,d)36Ca transfer reaction

Abstract

A recent sensitivity study has shown that the 35K(p,γ)36Ca reaction is one of the ten (p,γ) reaction rates that could significantly impact the shape of the calculated X-ray burst light curve. In this work, we propose to reinvestigate the 35K(p,γ)36Ca reaction rate, as well as related uncertainties, by determining the energies and decay branching ratios of 36Ca levels, within the Gamow window, in the 0.5 to 2 GK X-ray burst temperature range. These properties were studied using the one neutron pick-up transfer reaction 37Ca(p,d)36Ca in inverse kinematics using a radioactive beam of 37Ca at 48 MeV nucleon-1. The experiment performed at GANIL, used the liquid Hydrogen target CRYPTA, the MUST2 detector array for the detection of the light charged particles and a zero degree detection system for the outgoing heavy ions. The atomic mass of 36Ca is confirmed and new resonances have been proposed together with their proton decay branching ratios. This spectroscopic information, used in combination with recent theoretical predictions for the γ-width, were used to calculate the 35K(p,γ)36Ca reaction rate. The recommended rate of the present work was obtain within a uncertainty factor of 2 at 1 sigma. This is consistent, with the previous estimate in the X-ray burst temperature range. A large increase of the reaction rate was found at higher temperatures due to two newly discovered resonances. The 35K(p,γ)36Ca thermonuclear reaction rate is now well constrained by the present work in a broad range of temperatures. Our results show that the 35K(p,γ)36Ca reaction does not affect the shape of the X-ray burst light curve, and that it can be removed from the list of the few influential proton radiative captures reactions having a strong impact on the light curve.