Transient Porosity Resulting from Fluid–Mineral Interaction and its Consequences

1区 地球科学 Q1 Earth and Planetary Sciences Reviews in Mineralogy & Geochemistry Pub Date : 2015-01-01 DOI:10.2138/RMG.2015.80.01
A. Putnis
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引用次数: 103

Abstract

The term porosity is very widely used in geosciences and normally refers to the spaces between the mineral grains or organic material in a rock, measured as a fraction of the total volume. These spaces may be filled with gas or fluids, and so the most common context for a discussion of porosity is in hydrogeology and petroleum geology of sedimentary rocks. While porosity is a measure of the ability of a rock to include a fluid phase, permeability is a measure of the ability for fluids to flow through the rock, and so depends on the extent to which the pore spaces are interconnected, the distribution of pores and pore neck size, as well as on the pressure driving the flow. This chapter will be primarily concerned with how reactive fluids can move through ‘tight rocks’ which have a very low intrinsic permeability and how secondary porosity is generated by fluid–mineral reactions. A few words about the meaning of the title will help to explain the scope of the chapter: 1. “Fluid–mineral interaction”: When a mineral is out of equilibrium with a fluid, it will tend to dissolve until the fluid is saturated with respect to the solid mineral. We will consider fluids to be aqueous solutions, although many of the principles described here also apply to melts. The generation of porosity by simply dissolving some minerals in a rock is one obvious way to enhance fluid flow. Dissolution of carbonates by low pH solutions to produce vugs and even caves would be one example. However, when considering the role of fluid–mineral reaction during metamorphism the fluid provides mechanisms that enable re-equilibration of the rock, i.e., by replacing one assemblage of minerals by a more stable assemblage. This not only involves the dissolution of the parent mineral phases, but the …
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流体-矿物相互作用导致的瞬态孔隙度及其后果
孔隙度这个术语在地球科学中被广泛使用,通常是指岩石中矿物颗粒或有机物质之间的空间,以总体积的一部分来衡量。这些空间可能充满气体或流体,因此讨论孔隙度的最常见背景是沉积岩的水文地质学和石油地质学。孔隙度是衡量岩石包含流体相的能力,而渗透率是衡量流体流过岩石的能力,因此取决于孔隙空间相互连接的程度、孔隙分布和孔颈大小,以及驱动流体流动的压力。本章将主要关注反应性流体如何穿过“致密岩石”,这些岩石具有非常低的固有渗透率,以及流体-矿物反应如何产生次生孔隙。关于标题的含义的几句话将有助于解释本章的范围:“流体-矿物相互作用”:当一种矿物与一种流体失去平衡时,它将倾向于溶解,直到流体相对于固体矿物达到饱和。我们将把流体视为水溶液,尽管这里描述的许多原理也适用于熔体。通过简单地溶解岩石中的一些矿物质来产生孔隙是增强流体流动的一种明显方法。低pH值溶液溶解碳酸盐产生孔洞甚至洞穴就是一个例子。然而,当考虑到流体-矿物反应在变质作用中的作用时,流体提供了使岩石重新平衡的机制,即通过用更稳定的矿物组合取代一种矿物组合。这不仅涉及到母矿相的溶解,还涉及到…
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来源期刊
Reviews in Mineralogy & Geochemistry
Reviews in Mineralogy & Geochemistry 地学-地球化学与地球物理
CiteScore
8.30
自引率
0.00%
发文量
39
期刊介绍: RiMG is a series of multi-authored, soft-bound volumes containing concise reviews of the literature and advances in theoretical and/or applied mineralogy, crystallography, petrology, and geochemistry. The content of each volume consists of fully developed text which can be used for self-study, research, or as a text-book for graduate-level courses. RiMG volumes are typically produced in conjunction with a short course but can also be published without a short course. The series is jointly published by the Mineralogical Society of America (MSA) and the Geochemical Society.
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