Type I X-ray bursts are thermonuclear explosions on the surface of accreting neutron stars. Hydrogen rich X-ray bursts burn protons far from the line of stability and can release energy in the form of neutrinos from β -decays. We have estimated, for the first time, the neutrino fluxes of Type I bursts for a range of initial conditions based on the predictions of a 1D implicit hydrodynamics code, Kepler , which calculates the complete nuclear reaction network. We find that neutrino losses are between and 0.14 of the total energy per nucleon, , depending upon the hydrogen fraction in the fuel. These values are significantly below the 35% value for neutrino losses often adopted in recent literature for the rp -process. The discrepancy arises because it is only at β -decays that of energy is lost due to neutrino emission, whereas there are no neutrino losses in and reactions. Using the total measured burst energies from Kepler for a range of initial conditions, we have determined an approximation formula for the total energy per nucleon released during an X-ray burst, , where is the average hydrogen mass fraction of the ignition column, with an rms error of . We provide a detailed analysis of the nuclear energy output of a burst and find an incomplete extraction of mass excess in the burst fuel, with 14% of the mass excess in the fuel not being extracted.
CITATION STYLE
Goodwin, A. J., Heger, A., & Galloway, D. K. (2019). Neutrino Losses in Type I Thermonuclear X-Ray Bursts: An Improved Nuclear Energy Generation Approximation. The Astrophysical Journal, 870(2), 64. https://doi.org/10.3847/1538-4357/aaeed2
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