Mass-loss, composition and observational signatures of stellar winds from X-ray bursts

Abstract

X-Ray bursts (XRBs) are powerful thermonuclear events on the surface of accreting neutron stars (NSs), which can synthesize intermediate-mass elements. Although the high surface gravity prevents an explosive ejection, a small fraction of the envelope may be ejected by radiation-driven winds. In our previous works, we have developed a non-relativistic radiative wind model and coupled it to an XRB hydrodynamic simulation. We now apply this technique to another model featuring consecutive bursts. We determine the mass-loss and chemical composition of the wind ejecta. Results show that, for a representative XRB, about 0.1\% of the envelope mass is ejected per burst, at an average rate of 3.9 × 10-12\,M yr-1. Between 66\% and 76\% of the ejecta composition is 60Ni, 64Zn, 68Ge, 4He and 58Ni. We also report on the evolution of observational quantities during the wind phase and simulate NICER observations that resemble those of 4U 1820-40.

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