CAPILARITY AND SOLUTE TRANSPORT IN SWELLING AND SHRINKING SOILS

Soil Forming Factors and Processes from the Temperate Zone Pub Date : 1900-01-01 DOI:10.15551/FPPZT.V12I2.500

G. Rogobete, D. Țărău, D. Dicu, R. Bertici

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引用次数: 1

Abstract

The Aranca Low Plain (SW of Romania), with accumulative relief, a slow dip and an obvious subsidence, is covered with fluvio-lacustrine deposits with various grain sizes, from gravels to smectite clays. The phreatic waters are mineralized and sodium ions reach into the colloidal complex, destroying soil structure. The rise of water in the soil from a free water surface has been termed capillarity rise. The maximum height to which water may rise through capillarity varies between 1.5 and 4 m in Fluvisols and Vertisols. Capillarity rise of soil water takes place above the ground water level and is due to matric suction. The complex geometry of soil pare space creates numerous combinations of interfaces, capillaries and wedges in which water is retained. In addition, water is absorbed on to solid surfaces, with considerable force at close distances. Solutes can interact strongly with soil surfaces and their transport can be slowed in a process known as retardation. In Fluvisols, like in Chernozems and Phaeozems, soluble salts are concentrated in the first 50 cm of the soil profile, while in Vertisols most soluble salts are concentrated at the bottom of the profile. The water potential in a Vertisol is the sum of gravitational potential, capillarity potential and overburden potential. The overburden potential is related to civil engineers effective stress. The phenomenon of capillarity is thus dependent on solid and liquid interfacial properties such as surface tension, contact, angle and solid surface roughness and geometry. These phenomena, partial attributed to capillarity, determine retention and movement of water and solutes through soils.

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膨胀和收缩土壤中的毛细性和溶质运移

罗马尼亚西南部的Aranca低平原具有堆积起伏、缓慢倾斜和明显沉降的特点，覆盖着从砾石到蒙脱石粘土等不同粒度的河流湖相沉积。潜水被矿化，钠离子进入胶体复合体，破坏土壤结构。土壤中水分从自由水面上升的现象被称为毛细上升。水可以通过毛细作用上升到的最大高度在河流和河流中在1.5到4米之间变化。土壤水分的毛细上升发生在地下水位以上，是由于基质的吸力。土壤空间的复杂几何形状创造了许多界面、毛细血管和楔形的组合，其中保留了水。此外，水在近距离上以相当大的力被固体表面吸收。溶质可以与土壤表面发生强烈的相互作用，并且在一个称为阻滞的过程中，它们的运输可以减慢。与黑钙土和非黑钙土一样，在河流土壤中，可溶性盐集中在土壤剖面的前50厘米处，而在河流土壤中，大多数可溶性盐集中在剖面的底部。垂直土层中的水势是重力势、毛细势和覆盖层势的总和。覆盖层电位与土木工程师有效应力有关。因此，毛细现象取决于固体和液体的界面性质，如表面张力、接触、角度和固体表面粗糙度和几何形状。这些现象部分归因于毛细作用，决定了水和溶质在土壤中的滞留和运动。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Soil Forming Factors and Processes from the Temperate Zone

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