β-decay properties of some astrophysically important Sc-isotopes
Abstract
In the late progressive stages of heavy stars, electron capture and β-decay are the governing processes. The weak rates are essential inputs for modeling the stages of high-mass stars before supernova explosions. As per results obtained from previous simulations, weak rates of Scandium isotopes contribute substantially in changing the lepton-to-baryon ratio (Ye) of the nuclear matter in the core. In the present analysis, we report important β--decay properties of crucial Sc isotopes in an astrophysical environment with mass numbers 49 ≤ A ≤ 54. The investigation includes Gamow-Teller (GT) strength distributions, terrestrial half-lives, and stellar rates of electron capture (EC) and β--decay reactions. The calculations are performed using the proton-neutron (pn) quasi-particle random phase approximation (QRPA) model over a wide temperature range (107-3 × 1010 K) and density range (101 - 1011 g/cm3). Additionally, we compare our calculated results with available experimental and theoretical data. A good agreement is observed between our calculated half-lives and experimentally measured values. Our weak β--decay and EC rates are compared with those from the Independent-Particle Model (IPM) and Large-Scale Shell Model (LSSM). At high stellar temperatures and densities, our calculated β--decay rates are smaller than those from the other models.
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