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W2296617070 abstract "In this paper, we study the role of the symmetry energy on the neutron-drip transition in both nonaccreting and accreting neutron stars, allowing for the presence of a strong magnetic field as in magnetars. The density, pressure, and composition at the neutron-drip threshold are determined using the recent set of the Brussels-Montreal microscopic nuclear mass models, which mainly differ in their predictions for the value of the symmetry energy $J$ and its slope $L$ in infinite homogeneous nuclear matter at saturation. Although some correlations between on the one hand the neutron-drip density, the pressure, the proton fraction and on the other hand $J$ (or equivalently $L$) are found, these correlations are radically different in nonaccreting and accreting neutron stars. In particular, the neutron-drip density is found to increase with $L$ in the former case, but decreases in the latter case depending on the composition of ashes from x-ray bursts and superbursts. We have qualitatively explained these different behaviors using a simple mass formula. We have also shown that the details of the nuclear structure may play a more important role than the symmetry energy in accreting neutron-star crusts." @default.
W2296617070 created "2016-06-24" @default.
W2296617070 creator A5002358217 @default.
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W2296617070 creator A5056628959 @default.
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W2296617070 date "2016-01-15" @default.
W2296617070 modified "2023-09-24" @default.
W2296617070 title "Role of the symmetry energy on the neutron-drip transition in accreting and nonaccreting neutron stars" @default.
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W2296617070 doi "https://doi.org/10.1103/physrevc.93.015801" @default.
W2296617070 hasPublicationYear "2016" @default.
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