Experimental insights into the mineralogy and melt-rock reactions produced by lunar cumulate mantle overturn

IF 3.5 2区 地球科学 Q1 GEOCHEMISTRY & GEOPHYSICS
J. L. Scholpp, N. Dygert
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Abstract

Hybridization of the lunar mantle during the overturn (sinking) of Fe- and Ti–rich ilmenite-bearing clinopyroxenite cumulates (IBC) in the lunar interior is called upon to explain the high TiO2 abundances of lunar basalts. Chemical reactions that occur after juxtaposition of IBC and mantle peridotite are poorly constrained. We experimentally investigated these reactions in experiments that adjoin an IBC glass against presynthesized dunite in a reaction couple at temperatures of 1100–1300 °C and pressures of 0.5–2.02 GPa for 0.33–31.66 h. These conditions produced experiments near to well above the solidus temperature of the IBC. Near solidus experiments produce garnet in the IBC at 2 GPa. Supersolidus experiments exhibit dissolution of olivine material into the IBC melt and the formation of clinopyroxene at the IBC melt-dunite interface. Dunite dissolution is attributed to the olivine undersaturated composition of the IBC melt. In both near- and supersolidus experiments, compositional variations produced by solid-state diffusion across the IBC melt-dunite interface are observed. When pressure increases, temperature decreases, or IBC melts become closer to olivine saturation, dissolution slows, and the effects of solid-state diffusion in the dunite become more evident. Similar chemical exchange reactions would occur in the lunar mantle as downwelling IBC and lunar peridotites are juxtaposed by cumulate overturn. Hybridized lunar mantle sources are expected to contain 47–84% normative peridotite and 16–53% IBC. Simple numerical simulations suggest that in addition to dissolution–precipitation reactions, mechanical mixing may be required to produce volumetrically significant hybridized mantle sources over geologically-relevant timescales.

Abstract Image

Abstract Image

月球积层地幔倾覆产生的矿物学和熔岩反应的实验启示
月球内部富含铁和钛的钛锰矿积块(IBC)在翻转(下沉)过程中发生的月幔杂化被用来解释月球玄武岩的高TiO2丰度。IBC 与地幔橄榄岩并置后发生的化学反应还没有得到很好的解释。我们在温度为 1100-1300 ℃、压力为 0.5-2.02 GPa、持续时间为 0.33-31.66 小时的实验中研究了这些反应。接近凝固温度的实验在 2 GPa 的压力下在 IBC 中产生石榴石。超固相实验显示橄榄石材料溶解到 IBC 熔体中,并在 IBC 熔体-辉绿岩界面形成霞石。辉石的溶解是由于 IBC 熔体中橄榄石成分未饱和造成的。在近固态和超固态实验中,都观察到了固态扩散穿过 IBC 熔体-辉绿岩界面所产生的成分变化。当压力升高、温度降低或 IBC 熔体更接近橄榄石饱和度时,溶解速度会减慢,固态扩散在云母岩中的作用会变得更加明显。当下沉的IBC和月球橄榄岩因堆积物翻转而并置时,类似的化学交换反应也会在月幔中发生。杂化月幔源预计含有 47-84% 的标准橄榄岩和 16-53% 的 IBC。简单的数值模拟表明,除了溶解-沉淀反应外,可能还需要机械混合,才能在地质相关的时间尺度上产生体积显著的杂化地幔源。
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来源期刊
Contributions to Mineralogy and Petrology
Contributions to Mineralogy and Petrology 地学-地球化学与地球物理
CiteScore
6.50
自引率
5.70%
发文量
94
审稿时长
1.7 months
期刊介绍: Contributions to Mineralogy and Petrology is an international journal that accepts high quality research papers in the fields of igneous and metamorphic petrology, geochemistry and mineralogy. Topics of interest include: major element, trace element and isotope geochemistry, geochronology, experimental petrology, igneous and metamorphic petrology, mineralogy, major and trace element mineral chemistry and thermodynamic modeling of petrologic and geochemical processes.
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