Doppler Broadening in 20Mg(β pγ)19Ne Decay

Abstract

Background: The 15O(α ,γ)19Ne bottleneck reaction in Type I x-ray bursts is the most important thermonuclear reaction rate to constrain experimentally, in order to improve the accuracy of burst light-curve simulations. A proposed technique to determine the thermonuclear rate of this reaction employs the 20Mg(β pα)15O decay sequence. The key 15O(α ,γ)19Ne resonance at an excitation of 4.03 MeV is now known to be fed in 20Mg(β pγ)19Ne; however, the energies of the protons feeding the 4.03 MeV state are unknown. Knowledge of the proton energies will facilitate future 20Mg(β p α)15O measurements. Purpose: To determine the energy of the proton transition feeding the 4.03 MeV state in 19Ne. Method: A fast beam of 20Mg was implanted into a plastic scintillator, which was used to detect β particles. 16 high purity germanium detectors were used to detect γ rays emitted following β p decay. A Monte Carlo method was used to simulate the Doppler broadening of 19Ne γ rays and compare to the experimental data. Results: The center of mass energy between the proton and 19Ne, feeding the 4.03 MeV state, is measured to be 1.21+0.25-0.22 MeV, corresponding to a 20Na excitation energy of 7.44+0.25-0.22 MeV. Absolute feeding intensities and γ-decay branching ratios of 19Ne states were determined including the 1615 keV state. A new γ decay branch from the 1536 keV state in 19Ne to the ground state is reported. The lifetime of the 1507 keV state in 19Ne is measured to be 4.3+1.3-1.1 ps resolving discrepancies in the literature. Conflicting 20Mg(β p) decay schemes in published literature are clarified.