C

c – canicula Pub Date : 1968-12-31 DOI:10.1515/9783112586723-001

L. Sigalotti, F. Felice, Judith Daza-Montero

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Abstract

Most early radiative transfer calculations of protostellar collapse have suggested an upper limit of ∼40 M for the final stellar mass before radiation pressure can exceed the star’s gravitational pull and halt the accretion. Here we perform further collapse calculations, using frequency-dependent radiation transfer coupled to a frequency-dependent dust model that includes amorphous carbon particles, silicates, and ice-coated silicates. The models start from pressure-bounded, logatropic spheres of mass between 5 M and 150 M with an initial nonsingular density profile. We find that in a logatrope the infall is never reversed by the radiative forces on the dust and that stars with masses 100 M may form by continued accretion. Compared to previous models that start the collapse with a ρ ∝ r−2 density configuration, our calculations result in higher accretion times and lower average accretion rates with peak values of ∼5.8 × 10−5M yr−1. The radii and bolometric luminosities of the produced massive stars ( 90 M ) are in good agreement with the figures reported for detected stars with initial masses in excess of 100 M . The spectral energy distribution from the stellar photosphere reproduces the observed fluxes for hot molecular cores with peaks of emission from midto near-infrared.

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大多数关于原恒星坍缩的早期辐射转移计算表明，在辐射压力超过恒星的引力并停止吸积之前，最终恒星质量的上限为~ 40 M。在这里，我们使用频率相关的辐射转移耦合到频率相关的尘埃模型，包括无定形碳颗粒、硅酸盐和冰包硅酸盐，进行进一步的崩塌计算。该模型从5 - 150 M之间的压力有界的对数变球开始，具有初始非奇异密度剖面。我们发现，在一个黑洞中，尘埃的辐射力永远不会逆转下落，质量为100 M的恒星可能会通过持续的吸积而形成。与先前以ρ∝r−2密度配置开始坍缩的模型相比，我们的计算结果表明吸积时间更长，平均吸积速率更低，峰值为~ 5.8 × 10−5M yr−1。所产生的大质量恒星(90 M)的半径和热光度与已发现的初始质量超过100 M的恒星的数据非常吻合。来自恒星光球的光谱能量分布再现了观测到的热分子核的通量，其发射峰来自中至近红外。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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c – canicula

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