土层厚度对植被土壤干燥开裂行为的影响

Congying Li , Qing Cheng , Chaosheng Tang , Yingdong Gu , Lingxin Cui , Haowen Guo
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引用次数: 0

摘要

本研究的目的是探索不同的土层厚度如何影响植被土壤的干燥开裂行为。在实验过程中,使用电子天平对水分蒸发进行量化,同时使用数码相机捕捉土壤表面开裂的开始和发展过程。结果表明,在早期干燥过程中,植被土壤的蒸发率与叶片生物量呈正相关。在相同土层厚度的土壤样本中,植被土壤样本的恒定速率阶段持续时间始终短于裸露土壤样本。随着土层厚度的增加,植被土壤样本和裸露土壤样本都会在含水量较高时开裂。然而,植被土壤样本在含水量较低时就会比裸露土壤样本开裂。植被大大降低了土壤表面的裂缝率,提高了土壤的抗裂性。裂缝减少率与根重和长度密度呈正相关。在较厚的植被土层中,最终表面裂缝长度明显减少。
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Effects of layer thickness on desiccation cracking behaviour of a vegetated soil

The objective of this study is to explore how different layer thicknesses affect the desiccation cracking behaviour of vegetated soil. During the experiment, an electronic balance was employed to quantify water evaporation, while a digital camera was utilized to capture the initiation and progression of soil surface cracking. Results indicate that in the early drying process, the rate of evapotranspiration in vegetated soil correlates positively with leaf biomass. For soil samples with the same layer thickness, the constant rate stage duration is consistently shorter in vegetated soil samples than in their bare soil counterparts. As the layer thickness increases, both vegetated and bare soil samples crack at higher water content. However, vegetated soil samples crack at lower water content than their bare soil counterparts. Vegetation significantly reduces the soil surface crack ratio and improves the soil crack resistance. The crack reduction ratio is positively correlated with both root weight and length density. In thicker vegetated soil layers, the final surface crack length noticeably declines.

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