Magnesiowüstite as a major nitrogen reservoir in Earth’s lowermost mantle

IF 3.4 1区地球科学 Q1 GEOCHEMISTRY & GEOPHYSICS

Geochemical Perspectives Letters Pub Date : 2024-01-05 DOI:10.7185/geochemlet.2401

G. Rustioni, M. Wiedenbeck, N. Miyajima, A. Chanyshev, H. Keppler

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Abstract

Ferropericlase (Mg,Fe)O is after bridgmanite the most abundant phase in the lower mantle. The ultralow velocity zones above the core-mantle boundary may contain very Fe-rich magnesiowüstite (Fe,Mg)O, possibly as result of the fractional crystallisation of a basal magma ocean. We have experimentally studied the solubility of nitrogen in the ferropericlase-magnesiowüstite solid solution series as function of iron content. Multi-anvil experiments were performed at 20–33 GPa and 1600–1800 °C in equilibrium with Fe metal. Nitrogen solubility increases from a few tens ppm (μg/g) for Mg-rich ferropericlase to more than 10 wt. % for nearly pure wüstite. Such high solubilities appear to be due to solid solution with NiAs-type FeN. Our data suggest that during fractional crystallisation of a magma ocean, the core-mantle boundary would have become extremely enriched with nitrogen, such that the deep mantle today could be the largest nitrogen reservoir on Earth. The often discussed “subchondritic N/C” ratio of the bulk silicate Earth may be an artefact of insufficient sampling of this deep reservoir.

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作为地球最下层地幔主要氮库的菱镁矿

铁闪长岩（Mg,Fe）O 是继桥粒岩之后下地幔中含量最高的相。地核-地幔边界上方的超低速度区可能含有非常丰富的铁镁锰矿（Fe,Mg）O，这可能是基底岩浆洋分化结晶的结果。我们通过实验研究了氮在铁闪长岩-镁闪长岩固溶体系列中的溶解度与铁含量的函数关系。我们在 20-33 GPa 和 1600-1800 °C 温度条件下，在与金属铁平衡的状态下进行了多安培实验。氮的溶解度从富含镁的铁绿泥石的几十ppm（μg/g）增加到近乎纯净的绿泥石的超过10 wt.%。如此高的溶解度似乎是由于与 NiAs 型 FeN 的固溶所致。我们的数据表明，在岩浆海的碎裂结晶过程中，岩芯-地幔边界的氮含量会变得非常丰富，因此今天的深地幔可能是地球上最大的氮库。人们经常讨论的大块硅酸盐地球的 "亚软岩氮/碳 "比率可能是对这一深层储藏取样不足的一个假象。

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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来源期刊

Geochemical Perspectives Letters Earth and Planetary Sciences-Geochemistry and Petrology

CiteScore

7.00

自引率

2.00%

发文量

审稿时长

15 weeks

期刊介绍： Geochemical Perspectives Letters is an open access, internationally peer-reviewed journal of the European Association of Geochemistry (EAG) that publishes short, highest-quality articles spanning geochemical sciences. The journal aims at rapid publication of the most novel research in geochemistry with a focus on outstanding quality, international importance, originality, and stimulating new developments across the vast array of geochemical disciplines.