The relationships between the effective surface temperature T_(eff) and the internal temperature T_b of nonmagnetized neutron stars with and without accreted envelopes are calculated for T_(eff) > 5 X 10~4 K. We use updated equations of state and radiative opacities, and we improve considerably the electron conductive opacity. We examine various models of accreted layers (H, He, C, and O subshells produced by nuclear burning of accreted matter). The resulting T_(eff)-T_b relationship is remarkably insensitive to the details of the models and depends mainly on the accreted mass ΔM. For T_(eff) > 10~5 K, the accreted matter is generally more heat transparent. Even a small accreted mass (ΔM approx> 10~(-13) solar mass) affects appreciably the cooling of a neutron star, leading to higher T_(eff) at the neutrino cooling stage and to lower T_(eff) at the subsequent photon stage. We illustrate this by simulating the standard cooling of neutron stars. The presence of accreted matter yields better agreement of our model cooling curves with the blackbody fits to the ROSAT spectral observations of cooling neutron stars, without invoking quark matter or superfluidity in the neutron star cores.
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机译:对于T_(eff)> 5 X 10〜4 K,计算了有和没有积壳的非磁化中子星的有效表面温度T_(eff)和内部温度T_b之间的关系。我们使用状态和辐射不透明性的更新方程,并且我们大大提高了电子导电的不透明度。我们研究了增生层的各种模型(由增生物质的核燃烧产生的H,He,C和O子壳)。产生的T_(eff)-T_b关系对模型的细节非常不敏感,并且主要取决于吸积质量ΔM。当T_(eff)> 10〜5 K时,吸积物通常更热透明。即使很小的吸积质量(ΔM约> 10〜(-13)太阳质量)也会显着影响中子星的冷却,从而导致中微子冷却阶段的T_(eff)更高,而随后的光子的T_(eff)更低。阶段。我们通过模拟中子星的标准冷却来说明这一点。积聚物质的存在使我们的模型冷却曲线与黑体更好地吻合,从而符合冷却中子星的ROSAT光谱观测,而无需在中子星核中调用夸克物质或超流动性。
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