植物岩:硅在土壤和植物中的持久性和释放——综述

A. Senthilkumar, B. Saliha, P. Pandian, R. T. Vendan, A. Gurusamy, P. Mahendran
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引用次数: 0

摘要

植物岩是由地下水和一些植物携带的二氧化硅形成的。地球表面硅酸盐矿物的风化作用提供了大量的可溶性二氧化硅,其中一些被生长的植物吸收。在溶液中,二氧化硅以单硅酸Si (OH4)的形式存在,pH值为2 ~ 9。它在维管系统中向上运输,并在叶片气孔周围的蒸腾过程中集中起来。过饱和溶液开始聚合或凝胶化,然后固化并在一些植物细胞内部和细胞之间形成固体乳白色二氧化硅(SiO2:nH2O)体(植物岩)。从7.4 m黄土岩心提取植物岩,并对其遮挡碳进行形态和同位素分析。植物和植物岩之间的同位素分馏率是通过测量许多现代乔木、蕨类和禾草物种来确定的。使用植物岩生物炭作为硅肥提供了不可否认的潜力,以减轻脱硅和增强硅生态服务,由于土壤风化和生物质去除。硅的积累水平等于或大于Poaceae, Equisetaceae和Cyperaceae等植物物种的必需营养素。然而,土壤中硅的丰度并不表明有足够的可溶硅供植物吸收。
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Phytoliths: Persistence & Release of Silicon in Soil and Plants – A Review
Phytoliths are formed from silica carried up from groundwater and some plants. The weathering of silicate minerals at the Earth’s surface provides large amounts of soluble silica, some of which is absorbed by growing plants. In solution, silica exists as mono silicic acid Si (OH4) with pH values of 2–9. It is carried upward in the vascular system and becomes concentrated during transpiration around the leaf stomata. The supersaturated solution begins to polymerize or gel then solidifies and forms solid opaline silica (SiO2:nH2O) bodies (phytoliths) within and between some of the plant cells. Phytoliths were extracted from the 7.4 meter loess core and analyzed morphologically and isotopically from the occluded carbon. Rates of isotopic fractionation between plant and phytolith were determined by measurements from many modern tree, fern, and grass species. The use of phytolith biochar as a Si fertilizer offers the undeniable potential to mitigate desilication and to enhance Si ecological services due to soil weathering and biomass removal. Silicon is accumulated at levels equal to or greater than essential nutrients in plant species belonging to the families Poaceae, Equisetaceae, and Cyperaceae. However, the abundance of silicon in soils is not an indication that sufficient supplies of soluble silicon are available for plant uptake.
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