How Porosity Increases During Incipient Weathering of Crystalline Silicate Rocks

1区 地球科学 Q1 Earth and Planetary Sciences
A. Navarre‐Sitchler, S. Brantley, G. Rother
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引用次数: 89

Abstract

Weathering of bedrock to produce porous regolith, the precursor to biologically active soil and soluble mineral nutrients, creates the life-supporting matrix upon which Earth’s Critical Zone—the thin surface layer where rock meets life—develops (Ollier 1985; Graham et al. 1994; Taylor and Eggleston 2001). Water and nutrients locked up in low porosity bedrock are biologically inaccessible until weathering helps transform the inert rock into a rich habitat for biological activity. Weathering increases the water-holding capacity and nutrient accessibility of rock and regolith by increasing porosity and mineral surface area, affecting the particle-size distribution, and enhancing ecosystem diversity (Cousin et al. 2003; Certini et al. 2004; Zanner and Graham 2005). Especially in areas where soils are thin and climate is dry, the water stored in weathered rock is essential to ecosystem productivity and survival (Sternberg et al. 1996; Zwieniecki and Newton 1996; Hubbert et al. 2001; Witty et al. 2003). Removal of soluble material during weathering decreases the concentrations of major elements such as Ca, Na, and Mg and the overall mass of the solid, decreasing the bulk density and increasing porosity. These chemical and physical changes result in decreased uniaxial compressive strength and elastic moduli of the rock and increased infiltration of water through the weathered rock (Tugrul 2004). Porosity in intact bedrock is comprised of inter- and intra-granular pores developed during (re-) crystallization in igneous and metamorphic rocks or diagenesis in sedimentary rocks. As we conceptualize it, the conversion of low-permeability bedrock to regolith generally begins due to the transport of meteoric water into protolith through the large-scale fractures that are present as a result of regional tectonic factors or exhumation (Wyrick and Borchers 1981; Molnar et al. 2007). In zones near the fractures, water can infiltrate into the low-porosity rock …
结晶硅酸盐岩石在早期风化过程中孔隙度如何增加
基岩风化产生多孔风化层,这是生物活性土壤和可溶性矿物质营养物质的前身,创造了支持生命的基质,地球的关键地带——岩石与生命相遇的薄表层(Ollier 1985;Graham et al. 1994;Taylor and Eggleston 2001)。锁在低孔隙度基岩中的水和营养物质在生物上是不可接近的,直到风化作用帮助惰性岩石转变为生物活动的丰富栖息地。风化作用通过增加孔隙度和矿物表面积、影响颗粒大小分布和增强生态系统多样性,增加岩石和风化层的持水能力和养分可及性(Cousin et al. 2003;Certini et al. 2004;Zanner and Graham 2005)。特别是在土壤稀薄和气候干燥的地区,风化岩石中储存的水对生态系统的生产力和生存至关重要(Sternberg等人,1996;Zwieniecki and Newton 1996;Hubbert et al. 2001;Witty et al. 2003)。风化过程中可溶性物质的去除降低了主要元素如Ca、Na和Mg的浓度,降低了固体的总质量,降低了堆积密度,增加了孔隙率。这些化学和物理变化导致岩石的单轴抗压强度和弹性模量下降,并增加了水通过风化岩石的渗透性(Tugrul 2004)。完整基岩的孔隙由岩浆岩、变质岩(再)结晶或沉积岩成岩作用形成的粒间和粒内孔隙组成。在我们的概念中,低渗透基岩向风化层的转化通常是由于区域构造因素或挖掘导致的大规模裂缝将大气水输送到原岩中(Wyrick and Borchers 1981;Molnar et al. 2007)。在裂缝附近的区域,水可以渗透到低孔隙度的岩石中。
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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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