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多孔火山岩在脆韧性转变过程中的渗透率

The Permeability of Porous Volcanic Rock Through the Brittle-Ductile Transition.

作者信息

Heap Michael J, Meyer Gabriel G, Noël Corentin, Wadsworth Fabian B, Baud Patrick, Violay Marie E S

机构信息

CNRS Institut Terre et Environnement de Strasbourg UMR 7063 Université de Strasbourg Strasbourg France.

Institut Universitaire de France (IUF) Paris France.

出版信息

J Geophys Res Solid Earth. 2022 Jun;127(6):e2022JB024600. doi: 10.1029/2022JB024600. Epub 2022 Jun 20.

DOI:10.1029/2022JB024600
PMID:35864883
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9286468/
Abstract

The permeability of volcanic rock controls the distribution of pore fluids and pore fluid pressure within a volcanic edifice, and is therefore considered to influence eruptive style and volcano deformation. We measured the porosity and permeability of a porous volcanic rock during deformation in the brittle and ductile regimes. In the brittle regime, permeability decreases by a factor of 2-6 up to the peak stress due the closure of narrow pore throats but, following shear fracture formation, remains approximately constant as strain is accommodated by sliding on the fracture. In the ductile regime, permeability continually decreases, by up to an order of magnitude, as a function of strain. Although compaction in the ductile regime is localized, permeability is not reduced substantially due to the tortuous and diffuse nature of the compaction bands, the geometry of which was also influenced by a pore shape preferred orientation. Although the evolution of the permeability of the studied porous volcanic rock in the brittle and ductile regimes is qualitatively similar to that for porous sedimentary rocks, the porosity sensitivity exponent of permeability in the elastic regime is higher than found previously for porous sedimentary rocks. This exponent decreases during shear-enhanced compaction toward a value theoretically derived for granular media, suggesting that the material is effectively granulating. Indeed, cataclastic pore collapse evolves the microstructure to one that is more granular. Understanding how permeability can evolve in a volcanic edifice will improve the accuracy of models designed to assist volcano monitoring and volcanic hazard mitigation.

摘要

火山岩的渗透率控制着火山体内孔隙流体和孔隙流体压力的分布,因此被认为会影响喷发方式和火山变形。我们在脆性和韧性状态下对一种多孔火山岩在变形过程中的孔隙率和渗透率进行了测量。在脆性状态下,由于狭窄孔隙喉道的闭合,渗透率在达到峰值应力之前降低2至6倍,但在剪切断裂形成后,随着应变通过在裂缝上滑动来适应,渗透率大致保持恒定。在韧性状态下,渗透率随着应变不断降低,降幅可达一个数量级。尽管韧性状态下的压实作用是局部的,但由于压实带的曲折和弥散性质,渗透率并没有大幅降低,压实带的几何形状也受到孔隙形状择优取向的影响。尽管所研究的多孔火山岩在脆性和韧性状态下渗透率的演化在定性上与多孔沉积岩相似,但弹性状态下渗透率的孔隙率敏感指数高于此前在多孔沉积岩中发现的值。在剪切增强压实过程中,该指数朝着颗粒介质理论推导值降低,这表明材料实际上在发生粒化。确实,碎裂孔隙坍塌使微观结构演变为更具颗粒性的结构。了解火山体内渗透率如何演化将提高旨在辅助火山监测和减轻火山灾害的模型的准确性。

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Hydrothermal alteration of andesitic lava domes can lead to explosive volcanic behaviour.安山质熔岩穹丘的热液蚀变会导致火山爆发行为。
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The permeability of fractured rocks in pressurised volcanic and geothermal systems.受加压影响的火山与地热系统中裂隙岩石的渗透性。
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Sintering of polydisperse viscous droplets.多分散粘性液滴的烧结
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Bull Volcanol. 2015;77(6):55. doi: 10.1007/s00445-015-0938-7. Epub 2015 Jun 3.