Insights into saline soil cracking subjected to drying-wetting cycles

IF 2.3 4区 地球科学
Haoxuan Feng, Xuguang Xing, Liuchang Su, Chunzhe Zhang, Yubo Wang, Yibo Li, Weihua Wang
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Abstract

Soil salinization has become a global environmental issue, and soil cracking can lead to preferential flows and destabilize the developments of plant-soil system. However, little is known about saline soil cracking, especially under external drying-wetting (D-W) alternations. This study explored how soil salt and continuous D-W cycles affected water evaporation and crack development responding to soil salinity (0, 0.3, 0.6, 1.0, and 2.0%, w/w) and three D-W cycles. Observed findings showed that saline soil water evaporation was smaller than nonsaline soil. Besides, the water evaporation decreased and increased as the soil salinity increased and the D-W cycles progressed, respectively. In addition, soil salt and D-W cycle inhibited and promoted soil cracking, respectively; specifically, the crack area density decreased and increased with increasing soil salinity and number of D-W cycles, respectively. Correlations indicated that the soil salt had overall larger contributions than the D-W cycle to the variations of water evaporation and crack development. Soil salt was negatively correlated with cumulative evaporation, evaporation rate, and crack length density, but was positively correlated with soil moisture; besides, D-W cycle was negatively correlated with soil moisture, but was positively correlated with cumulative evaporation, evaporation rate, crack area density, and crack length density. Mechanism exploration suggested that the salts inhibit surface cracking by promoting inter-microaggregate cementation and clay flocculation and blocking soil macropores; and the D-W cycle promotes surface cracking through the swelling-induced crack healing in the case of hydrophilic clay minerals in contact with water.

Abstract Image

盐碱土壤在干燥-湿润循环中开裂的启示
土壤盐碱化已成为一个全球性的环境问题,土壤开裂会导致优先流动,破坏植物-土壤系统的稳定发展。然而,人们对盐碱地开裂,尤其是外部干燥-湿润(D-W)交替条件下的开裂知之甚少。本研究探讨了土壤盐分和连续的干湿交替循环如何影响水分蒸发和裂缝发展,并对土壤盐分(0、0.3、0.6、1.0 和 2.0%,w/w)和三个干湿交替循环做出了响应。观察结果表明,盐碱地的水分蒸发量小于非盐碱地。此外,随着土壤盐度的增加和 D-W 周期的延长,水分蒸发量分别减少和增加。此外,土壤盐分和 D-W 周期分别抑制和促进了土壤开裂;具体而言,随着土壤盐分和 D-W 周期次数的增加,裂缝面积密度分别减小和增大。相关性表明,土壤盐分对水分蒸发和裂缝发展变化的总体贡献大于 D-W 循环。土壤盐分与累积蒸发量、蒸发速率和裂缝长度密度呈负相关,但与土壤水分呈正相关;此外,D-W 周期与土壤水分呈负相关,但与累积蒸发量、蒸发速率、裂缝面积密度和裂缝长度密度呈正相关。机理探讨表明,盐类通过促进微团聚体间的胶结和粘土絮凝以及阻塞土壤大孔隙来抑制表面开裂;而在亲水性粘土矿物与水接触的情况下,D-W 循环通过膨胀引起的裂缝愈合来促进表面开裂。
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来源期刊
Acta Geophysica
Acta Geophysica GEOCHEMISTRY & GEOPHYSICS-
CiteScore
3.80
自引率
13.00%
发文量
251
期刊介绍: Acta Geophysica is open to all kinds of manuscripts including research and review articles, short communications, comments to published papers, letters to the Editor as well as book reviews. Some of the issues are fully devoted to particular topics; we do encourage proposals for such topical issues. We accept submissions from scientists world-wide, offering high scientific and editorial standard and comprehensive treatment of the discussed topics.
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