Melt inclusions in spinel from a composite mantle xenolith

IF 2.6 3区地球科学 Q2 GEOCHEMISTRY & GEOPHYSICS

Chemie Der Erde-Geochemistry Pub Date : 2024-05-01 DOI:10.1016/j.chemer.2024.126118

Ioannis Baziotis , Myrto Simopoulou , Constantinos Mavrogonatos , Stephan Klemme , Jasper Berndt , Paul D. Asimow

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Abstract

Composite mantle xenoliths from the Cima Volcanic Field (CA, USA) contain a variety of melt (now glassy) inclusions hosted within mantle phases. The compositions and textures of these melt inclusions have the potential to constrain their trapping processes, melt sources, and the rates of ascent of their parent xenoliths. Here we focus on unusual spinel-hosted melt inclusions from one composite xenolith, reporting glass and daughter mineral compositions and textures and attempting to reconstruct inclusion bulk compositions. The xenolith contains spinel-hosted melt inclusions in its harzburgite, olivine-websterite and lherzolite layers; there are none in its orthopyroxenite layer.

The glass compositions and reconstructed bulk compositions of the partly-crystallized inclusions correspond to alkaline intermediate melts, mostly trachyandesites. Such melts are most likely to be generated and trapped by vapor-undersaturated phlogopite or amphibole dehydration melting to an assemblage of liquid + spinel + olivine ± pyroxenes. We modeled the near-liquidus phase relations of the inclusion bulk compositions and noted the closest approach of each inclusion to simultaneous saturation with spinel and either phlogopite or amphibole, resulting in estimated trapping pressures of ∼0.5–1.5 GPa and temperatures of ∼1000–1100 °C. The large size of the hosting spinel grains suggests a slow process associated with these breakdown reactions, probably thinning of the lithosphere and steepening of the geotherm during regional extension.

A linear correlation between the vesicle area and inclusion area (as proxies for volume) suggests an in-situ exsolution process from melts of relatively uniform volatile initial contents, consistent with trapping of vapor-undersaturated melts that later exsolve vapor during cooling and daughter crystal growth. A negative correlation between the glass content in melt inclusions and the size of the inclusion itself suggests a control on the degree of crystallinity with the size. There appears to be a two-stage cooling history captured by the inclusions, forming first prismatic daughter crystals and large round vesicles at the wall of the inclusion, followed by quenching to form a mat of fine crystallites and small vesicles in most inclusions. We connect the final quench to rapid ascent of the xenolith in its host melt, which also triggered partial breakdown of remaining amphibole to fine glassy symplectites.

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复合地幔异岩石尖晶石中的熔融包裹体

来自西马火山场（美国加利福尼亚州）的复合地幔异长石包含多种寄存在地幔相中的熔融（现为玻璃状）包裹体。这些熔体包裹体的成分和质地有可能制约其捕获过程、熔体来源及其母体异长石的上升速率。在这里，我们重点研究了一块复合异岩石中不寻常的尖晶石寄存熔融包裹体，报告了玻璃和子矿物的成分和质地，并试图重建包裹体的主体成分。这块奇石的哈氏闪长岩、橄榄石-韦氏闪长岩和蛭石层中都含有尖晶石包裹体，而正长岩层中没有。这种熔体最有可能是由蒸汽不饱和的辉石或闪长岩脱水熔融成液体+尖晶石+橄榄石±辉石的组合体而产生和捕获的。我们模拟了包体成分的近液相关系，并注意到每个包体最接近尖晶石和辉石或闪石同时饱和的情况，从而估算出捕获压力为0.5-1.5 GPa，温度为1000-1100 °C。囊泡面积与包裹体面积（作为体积的代用指标）之间的线性相关关系表明，初始挥发物含量相对均匀的熔体具有原位外溶解过程，这与蒸汽不饱和熔体的捕获过程一致，这些熔体随后在冷却和子晶体生长过程中外泄蒸汽。熔体包裹体中的玻璃含量与包裹体本身的大小呈负相关，这表明结晶度受包裹体大小的控制。夹杂物似乎经历了两个阶段的冷却过程，首先在夹杂物壁形成棱柱形子晶体和大的圆形囊泡，然后进行淬火，在大多数夹杂物中形成由细小晶体和小囊泡组成的垫层。我们将最后的淬火与异质岩在其主熔体中的快速上升联系起来，这也引发了剩余闪石的部分分解，形成细小的玻璃状共闪石。

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来源期刊

Chemie Der Erde-Geochemistry 地学-地球化学与地球物理

CiteScore

7.10

自引率

0.00%

发文量

审稿时长

3.0 months

期刊介绍： GEOCHEMISTRY was founded as Chemie der Erde 1914 in Jena, and, hence, is one of the oldest journals for geochemistry-related topics. GEOCHEMISTRY (formerly Chemie der Erde / Geochemistry) publishes original research papers, short communications, reviews of selected topics, and high-class invited review articles addressed at broad geosciences audience. Publications dealing with interdisciplinary questions are particularly welcome. Young scientists are especially encouraged to submit their work. Contributions will be published exclusively in English. The journal, through very personalized consultation and its worldwide distribution, offers entry into the world of international scientific communication, and promotes interdisciplinary discussion on chemical problems in a broad spectrum of geosciences. The following topics are covered by the expertise of the members of the editorial board (see below): -cosmochemistry, meteoritics- igneous, metamorphic, and sedimentary petrology- volcanology- low & high temperature geochemistry- experimental - theoretical - field related studies- mineralogy - crystallography- environmental geosciences- archaeometry