崩塌岩心中氮的耗竭和分馏

P. Hily-Blant, G. Pineau des Forêts, A. Faure, D. Flower
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引用次数: 6

摘要

对太阳系彗星的氮同位素比率的测量显示出一个恒定的值,~140,比原太阳的比率低三倍,这是一个高度显著的差异,至今仍未得到解释。在坍缩的早期阶段对静态无星核心的观测证实了理论预期,即星际条件下氮的分馏对大多数物种来说是边际的。然而,观测到的N2H+同位素比率与模式预测不一致。我们对氮同位素储存库如何从星际云到彗星,更一般地说,如何演变到原太阳星云的理解上的这些差距,可能源于星际氮化学过程的缺失或误解。到目前为止,关于无星核中氮分馏的理论研究已经解决了它们演化的准静态阶段,因此动态坍缩对同位素比率的影响尚不清楚。本文研究了恒星前核心重力坍缩过程中14N和15N通过气相和颗粒吸附和解吸反应的分馏过程。最初的化学条件,通常是在几个Myr之后在稳定状态下获得的,表明气相的分馏程度很低,与早期的研究一致。然而,在崩塌过程中,含有14N和15N的物质在颗粒上的不同吸附速率导致15N:14N比增加,这与观察结果更吻合。此外,我们发现不同物种的同位素比率随密度的增加而变化。根据L183的CO丰度分布,我们发现坍缩必须在大约一个自由落体的时间尺度上发生[见PDF文件末尾]。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Depletion and fractionation of nitrogen in collapsing cores
Measurements of the nitrogen isotopic ratio in Solar System comets show a constant value, ~140, which is three times lower than the protosolar ratio, a highly significant difference that remains unexplained. Observations of static starless cores at early stages of collapse confirm the theoretical expectation that nitrogen fractionation in interstellar conditions is marginal for most species. Yet, observed isotopic ratios in N2H+ are at variance with model predictions. These gaps in our understanding of how the isotopic reservoirs of nitrogen evolve, from interstellar clouds to comets, and, more generally, to protosolar nebulae, may have their origin in missing processes or misconceptions in the chemistry of interstellar nitrogen. So far, theoretical studies of nitrogen fractionation in starless cores have addressed the quasi-static phase of their evolution such that the effect of dynamical collapse on the isotopic ratio is not known. In this paper, we investigate the fractionation of 14N and 15N during the gravitational collapse of a pre-stellar core through gas-phase and grain adsorption and desorption reactions. The initial chemical conditions, which are obtained in steady state after typically a few Myr, show low degrees of fractionation in the gas phase, in agreement with earlier studies. However, during collapse, the differential rate of adsorption of 14N- and 15N-containing species onto grains results in enhanced 15N:14N ratios, in better agreement with the observations. Furthermore, we find differences in the behavior, with increasing density, of the isotopic ratio in different species. We find that the collapse must take place on approximately one free-fall timescale, based on the CO abundance profile in L183 [see the end in the PDF file]
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