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通过多维电子显微镜和离散元建模解析蛇纹岩中的纳米级孔隙度

Decoding the nanoscale porosity in serpentinites from multidimensional electron microscopy and discrete element modelling.

作者信息

Chogani Alireza, Plümper Oliver

机构信息

Department of Earth Sciences, Utrecht University, Utrecht, The Netherlands.

出版信息

Contrib Mineral Petrol. 2023;178(11):78. doi: 10.1007/s00410-023-02062-4. Epub 2023 Oct 17.

DOI:10.1007/s00410-023-02062-4
PMID:38616804
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11008076/
Abstract

Serpentinites, widespread in Earth's lithosphere, exhibit inherent nanoporosity that may significantly impact their geochemical behaviour. This study provides a comprehensive investigation into the characteristics, scale dependence, and potential implications of nanoporosity in lizardite-dominated serpentinites. Through a combination of multidimensional imaging techniques and molecular-dynamics-based discrete element modelling, we reveal that serpentinites function as nanoporous media with pore sizes predominantly less than 100 nm. Crystallographic relationships between olivine, serpentine, and nanoporosity are explored, indicating a lack of significant correlations. Instead, stochastic growth and random packing of serpentine grains within mesh cores may result in interconnected porosity. The analysis of pore morphology suggests that the irregular pore shapes align with the crystal form of serpentine minerals. Furthermore, the nanoporosity within brucite-rich layers at the serpentine-olivine interface is attributed to delamination along weak van der Waals planes, while pore formation within larger brucite domains likely results from low-temperature alteration processes. The fractal nature of the pore size distribution and the potential interconnectivity of porosity across different scales further support the presence of a pervasive nanoporous network within serpentinites. Confinement within these nanopores may introduce unique emergent properties, potentially influencing fluid transport, mineral solubility, and chemical reactions. As such, these processes may have profound implications for the geochemical evolution of serpentinites.

摘要

蛇纹岩广泛分布于地球岩石圈,具有内在的纳米孔隙度,这可能会显著影响其地球化学行为。本研究对以利蛇纹石为主的蛇纹岩中纳米孔隙度的特征、尺度依赖性及潜在影响进行了全面调查。通过结合多维成像技术和基于分子动力学的离散元建模,我们发现蛇纹岩作为纳米多孔介质,其孔径主要小于100纳米。研究了橄榄石、蛇纹石与纳米孔隙度之间的晶体学关系,结果表明它们之间缺乏显著相关性。相反,网格状核心内蛇纹石颗粒的随机生长和随机堆积可能导致相互连通的孔隙度。孔隙形态分析表明,不规则的孔隙形状与蛇纹石矿物的晶体形态一致。此外,蛇纹石 - 橄榄石界面富含水镁石层内的纳米孔隙度归因于沿弱范德华面的分层,而较大水镁石域内的孔隙形成可能是低温蚀变过程的结果。孔径分布的分形性质以及不同尺度孔隙度的潜在连通性进一步支持了蛇纹岩中普遍存在纳米多孔网络。这些纳米孔隙内的限制可能会引入独特的涌现性质,可能影响流体传输、矿物溶解度和化学反应。因此,这些过程可能对蛇纹岩的地球化学演化具有深远影响。

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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/7775/11008076/c2f2a1de937c/410_2023_2062_Fig8_HTML.jpg
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