Rapid hydration and weakening of anhydrite under stress: implications for natural hydration in the Earth's crust and mantle

IF 3.2 2区地球科学 Q1 GEOCHEMISTRY & GEOPHYSICS

Solid Earth Pub Date : 2023-09-01 DOI:10.5194/se-14-985-2023

Johanna Heeb, D. Healy, N. Timms, E. Gomez‐Rivas

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引用次数: 0

Abstract

Abstract. Mineral hydration is an important geological process that influences the rheology and geochemistry of rocks and the fluid budget of the Earth's crust and mantle. Constant-stress differential compaction (CSDC) tests, dry and “wet” tests under confining pressure, and axial-stress tests were conducted for the first time to investigate the influence of triaxial stress on hydration in anhydrite–gypsum aggregates. Characterization of the samples before and after triaxial experiments was performed with optical and scanning electron microscopy, including energy-dispersive spectroscopy and electron backscatter diffraction mapping. Stress–strain data reveal that samples that underwent constant-stress differential compaction in the presence of fluids are ∼ 14 % to ∼ 41 % weaker than samples deformed under wet conditions. The microstructural analysis shows that there is a strong temporal and spatial connection between the geometry, distribution, and evolution of fractures and hydration products. The increasing reaction surface area in combination with pre-existing gypsum in a gypsum-bearing anhydrite rock led to rapid gypsification. The crystallographic orientations of newly formed vein gypsum have a systematic preferred orientation for long distances along veins, beyond the grain boundaries of wall-rock anhydrite. Gypsum crystallographic orientations in {100} and {010} are systematically and preferentially aligned parallel to the direction of maximum shear stress (45∘ to σ1). Gypsum is also not always topotactically linked to the wall-rock anhydrite in the immediate vicinity. This study proposes that the selective inheritance of crystal orientations from favourably oriented wall-rock anhydrite grains for the minimization of free energy for nucleation under stress leads to the systematic preferred orientation of large, new gypsum grains. A sequence is suggested for hydration under stress that requires the development of fractures accompanied by localized hydration. Hydration along fractures with a range of apertures up to 120 µm occurred in under 6 h. Once formed, gypsum-filled veins represent weak surfaces and are the locations of further shear fracturing, brecciation, and eventual brittle failure. These findings imply that non-hydrostatic stress has a significant influence on hydration rates and subsequent mechanical strength of rocks. This phenomenon is applicable across a wide range of geological environments in the Earth's crust and upper mantle.

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应力作用下硬石膏的快速水化和弱化:对地壳和地幔自然水化的启示

摘要矿物水化作用是影响岩石流变学和地球化学以及地壳和地幔流体平衡的重要地质过程。为研究三轴应力对硬石膏骨料水化的影响，首次开展了恒应力差压(CSDC)试验、围压下的干、湿试验以及轴向应力试验。利用光学和扫描电子显微镜对三轴实验前后的样品进行表征，包括能量色散光谱和电子背散射衍射成像。应力-应变数据显示，在流体存在下进行恒应力差压实的样品比在潮湿条件下变形的样品弱14%至41%。微观结构分析表明，裂缝的几何形状、分布和演化与水化产物之间存在很强的时空联系。在含石膏硬石膏岩中，随着反应表面积的增大，加之已有石膏的存在，导致了快速的石膏化。新形成的脉状石膏的晶体取向在沿脉体较长距离、超越围岩硬石膏晶界的范围内具有系统的优先取向。{100}和{010}的石膏晶体取向系统地优先平行于最大剪切应力方向(45°至σ1)。石膏在地形上也不总是与围岩硬石膏直接联系在一起。本研究提出，在应力作用下，为使成核自由能最小化，有利于取向的围岩硬石膏晶粒的取向选择性继承导致了大的新石膏晶粒的系统性择优取向。应力作用下的水化作用序列，要求裂缝发育时伴有局部水化作用。120µm裂缝的水化过程在6 h内完成。一旦形成，石膏充填的矿脉代表脆弱的表面，是进一步剪切破裂、角化和最终脆性破坏的位置。这些发现表明，非静水应力对岩石的水化速率和随后的机械强度有显著影响。这一现象适用于地壳和上地幔的各种地质环境。

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来源期刊

Solid Earth GEOCHEMISTRY & GEOPHYSICS-

CiteScore

6.90

自引率

8.80%

发文量

审稿时长

4.5 months

期刊介绍： Solid Earth (SE) is a not-for-profit journal that publishes multidisciplinary research on the composition, structure, dynamics of the Earth from the surface to the deep interior at all spatial and temporal scales. The journal invites contributions encompassing observational, experimental, and theoretical investigations in the form of short communications, research articles, method articles, review articles, and discussion and commentaries on all aspects of the solid Earth (for details see manuscript types). Being interdisciplinary in scope, SE covers the following disciplines: geochemistry, mineralogy, petrology, volcanology; geodesy and gravity; geodynamics: numerical and analogue modeling of geoprocesses; geoelectrics and electromagnetics; geomagnetism; geomorphology, morphotectonics, and paleoseismology; rock physics; seismics and seismology; critical zone science (Earth''s permeable near-surface layer); stratigraphy, sedimentology, and palaeontology; rock deformation, structural geology, and tectonics.