Noble gases in presolar diamonds I: Three distinct components and their implications for diamond origins

Meteoritics Pub Date : 1994-11-01 DOI:10.1111/J.1945-5100.1994.TB01094.X

G. Huss, R. Lewis

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引用次数: 229

Abstract

— High-purity separates of presolar diamond were prepared from 14 primitive chondrites from 7 compositional groups. Their noble gases were measured using stepped pyrolysis. Three distinct noble gas components are present in diamonds, HL, P3, and P6, each of which is found to consist of five noble gases. P3, released between 200 °C and 900 °C, has a “planetary” elemental abundance pattern and roughly “normal” isotopic ratios. HL, consisting of isotopically anomalous Xe-HL and Kr-H, Ar with high 38Ar/36Ar, and most of the gas making up Ne-A2 and He-A, is released between 1100 °C and 1600 °C. HL has “planetary” elemental ratios, except that it has much more He and Ne than other known “planetary” components. HL gases are carried in the bulk diamonds, not in some trace phase. P6 has a slightly higher median release temperature than HL and is not cleanly separated from HL by stepped pyrolysis. Our data suggest that P6 has roughly “normal” isotopic compositions and “planetary” elemental ratios. Both P3 and P6 seem to be isotopically distinct from P1, the dominant “planetary” noble-gas component in primitive chondrites. Release characteristics suggest that HL and P6 are sited in different carriers within the diamond fractions, while P3 may be sited near the surfaces of the diamonds. We find no evidence of separability of Xe-H and Xe-L or other isotopic variations in the HL component. However, because ∼1010 diamonds are required to measure a Xe composition, a lack of isotopic variability does not constrain diamonds to come from a single source. In fact, the high abundance of diamonds in primitive chondrites and the presence of at least three distinct noble-gas components strongly suggest that diamonds originated in many sources. Relative abundances of noble-gas components in diamonds correlate with degree of thermal processing (see companion paper), indicating that all meteorites sampled essentially the same mixture of diamonds. That mixture was probably inherited from the Sun's parent molecular cloud.

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太阳系前钻石中的惰性气体I:三种不同的成分及其对钻石起源的影响

-从7个组成群的14个原始球粒陨石中制备了高纯度的前太阳金刚石分离物。用分步热解法测量了它们的惰性气体。钻石中存在三种不同的稀有气体成分:HL、P3和P6，每一种都由五种稀有气体组成。P3在200°C到900°C之间释放，具有“行星”元素丰度模式和大致“正常”的同位素比率。在1100 ~ 1600℃之间释放出由同位素异常的Xe-HL和Kr-H组成的HL，高38Ar/36Ar的Ar，以及大部分由Ne-A2和He-A组成的气体。HL具有“行星”的元素比，除了它比其他已知的“行星”成分含有更多的He和Ne。高热气体是在钻石的整体中携带的，而不是在一些微量相中携带的。P6的中位释放温度略高于HL，并且不能通过分步热解从HL中分离出来。我们的数据表明P6具有大致“正常”的同位素组成和“行星”的元素比例。P3和P6似乎在同位素上与P1不同，P1是原始球粒陨石中主要的“行星”稀有气体成分。释放特性表明，HL和P6位于金刚石馏分内的不同载体上，而P3可能位于金刚石表面附近。我们没有发现在HL组分中存在Xe-H和Xe-L可分离性或其他同位素变化的证据。然而，由于测量Xe组成需要~ 1010颗钻石，因此缺乏同位素变异性并不限制钻石来自单一来源。事实上，原始球粒陨石中钻石的高丰度和至少三种不同的稀有气体成分的存在强烈表明，钻石起源于许多来源。钻石中稀有气体成分的相对丰度与热处理程度相关(见附文)，表明所有陨石取样基本上都是相同的钻石混合物。这种混合物可能是从太阳的母体分子云那里继承来的。

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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Meteoritics

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