黄土高原区物理结皮对坡面流土壤剥离的影响

IF 7.3 1区农林科学 Q1 ENVIRONMENTAL SCIENCES

International Soil and Water Conservation Research Pub Date : 2023-06-07 DOI:10.1016/j.iswcr.2023.05.006

Jiaxin Liu , Liding Chen , Bing Wang , Xiaoyu Peng

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引用次数: 0

摘要

物理结皮是表层土壤结构的重要组成部分，在黄土地区广泛存在。PSC被认为对土壤剥离过程有重要影响。然而，对于坡面流对土壤分离的长期影响及其机制，特别是在自然环境下，仍不清楚。为了研究土壤抗侵蚀能力的时间变化及其影响因素，在黄土高原一个8 × 8 m的土壤样地进行了524 d的自然暴露试验，其中包括两个雨季和一个冬季。采用不同PSC发展阶段的结壳(SC)和非结壳(NSC)土样，进行水槽试验，以确定在6种设计流剪应力水平(5.66 ~ 22.11 Pa)下的土壤剥离能力(Dc)。随后，计算了两个土壤抗侵蚀参数，细沟可蚀性(Kr)和临界剪应力(τc)。随着时间的推移，SC和NSC处理的Kr分别从0.516减小到0.120 s m−1和0.521减小到0.223 s m−1，而τc分别从0.49增大到4.42 Pa和0.26 ~ 2.46 Pa。土壤抗侵蚀能力在前1 ~ 2个月变化迅速，随后变化缓慢，之后略有波动。SC组的Kr比NSC组低42%，τc比NSC组高67%。两种处理对土壤性质的影响都很大。SC处理的SCT从0增加到7.09 mm。SC和NSC处理的Coh分别增加了2.91 ~ 9.04 kPa和3.01 ~ 4.78 kPa。SCT和Coh在SC处理下均能较好地预测土壤侵蚀阻力参数(R2≥0.82)，而NSC处理下的Coh预测效果最好(R2≥0.90)。结果表明，在自然条件下，黄土区土壤剥离过程中PSC的形成增强了土壤抗侵蚀能力。揭示了PSC在土壤侵蚀过程中的重要作用和复杂性，为准确认识和预测土壤侵蚀提供了理论和数据支持。

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Effects of physical crust on soil detachment by overland flow in the Loess Plateau region of China

Physical soil crust (PSC), a key component of surface soil structure, exists extensively in loess areas. PSC is considered to have a significant effect on soil detachment processes. However, the long-term effects and the corresponding mechanisms of PSC on soil detachment by overland flow are still not well understood, especially in natural environments. To investigate temporal variation in soil erosion resistance and the underlying factors during PSC formation, an 8 × 8-m soil plot was exposed to natural conditions in the Loess Plateau over a 524-day period spanning two rainy seasons and a winter between them. A flume test was conducted to determine soil detachment capacity (D_c) under six designed flow shear stress levels (5.66–22.11 Pa) using crusted (SC) and non-crusted (NSC) soil samples at different PSC development stages. Subsequently, two soil erosion resistance parameters, rill erodibility (K_r) and critical shear stress (τ_c), were calculated. Over time, in the SC and NSC treatments, K_r decreased from 0.516 to 0.120 s m⁻¹ and 0.521 to 0.223 s m⁻¹, respectively, while τ_c increased from 0.49 to 4.42 Pa and 0.26–2.46 Pa, respectively. Variation in soil erosion resistance was rapid in the first one to two months, and then slowed down, with slight fluctuations afterwards. In the SC treatment, K_r was 42% lower and τ_c was 67% greater than those in the NSC treatment. Soil properties changed greatly for both treatments. SCT increased from 0 to 7.09 mm in the SC treatment. Coh increased from 2.91 to 9.04 kPa and 3.01–4.78 kPa in SC and NSC treatments, respectively. Both soil erosion resistance parameters could be well predicted by SCT and Coh in the SC treatment (R² ≥ 0.82), while their best predictor was Coh in the NSC treatment (R² ≥ 0.90). The results demonstrate that PSC formation enhances soil erosion resistance in the soil detachment process in the loess region under natural conditions. Our study revealed the important role and complexity of PSC in the process of soil erosion, and provided theoretical and data support for accurate understanding and prediction of soil erosion.

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来源期刊

International Soil and Water Conservation Research Agricultural and Biological Sciences-Agronomy and Crop Science

CiteScore

12.00

自引率

3.10%

发文量

171

审稿时长

49 days

期刊介绍： The International Soil and Water Conservation Research (ISWCR), the official journal of World Association of Soil and Water Conservation (WASWAC) http://www.waswac.org, is a multidisciplinary journal of soil and water conservation research, practice, policy, and perspectives. It aims to disseminate new knowledge and promote the practice of soil and water conservation. The scope of International Soil and Water Conservation Research includes research, strategies, and technologies for prediction, prevention, and protection of soil and water resources. It deals with identification, characterization, and modeling; dynamic monitoring and evaluation; assessment and management of conservation practice and creation and implementation of quality standards. Examples of appropriate topical areas include (but are not limited to): • Conservation models, tools, and technologies • Conservation agricultural • Soil health resources, indicators, assessment, and management • Land degradation • Sustainable development • Soil erosion and its control • Soil erosion processes • Water resources assessment and management • Watershed management • Soil erosion models • Literature review on topics related soil and water conservation research