黄土高原植被对重力侵蚀的作用机理

doi:10.16843/j.sswc.2022.06.016

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摘要通过对重力侵蚀的研究手段、发生机理等国内外研究成果的述评,论述植被作用对小流域重力侵蚀产沙的影响,为黄土高原小流域生态治理规划提供参考。目前国内外主要采用现场监测、现场调查、现场试验及模型试验等方法来获取重力侵蚀原始数据并分析植被的作用。其中,现场试验和模型试验作为研究重力侵蚀微观机理的有效途径,能够展示植被对重力侵蚀作用的动态过程;遥感监测能够快速获取较大范围内的重力侵蚀数据,为水土保持宏观决策提供参考;同时现场监测和现场调查能够为模型试验结果的可靠性提供验证。重力侵蚀的发生是多因素共同作用的结果,特别是植被对重力侵蚀影响的机理复杂,需要更进一步分析以及科学客观的评价。未来有必要提出更合理的方法,深入研究植被恢复条件下重力侵蚀的发展机制,评价植被在小流域水土保持中的作用。

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	高航
	徐向舟
	李依杭

关键词 ：重力侵蚀, 植被, 土壤流失, 研究方法, 黄土高原

Abstract：[Background] Gravity erosion, mass failure on steep slope triggered by self-weight, is an important process controlling the sedimentary structures and growth patterns of the steep slope, and the gravity erosion is also one of the major sources causing large amount of soil loss to the lower reaches. Under the national strategy to promote the high-quality development in the Yellow River Basin, the relationship between the vegetation and gravity erosion in the ecological management on the Loess Plateau has received more and more attentions from China. [Methods] Using a comprehensive and selective citation of the references around the world together with an in-depth discussion, this paper discussesd the occurrence mechanisms and research methods of the gravity erosion, as well as the effects of vegetation on soil loss caused by gravity erosion in the small watersheds of the Loess Plateau under the ecological management. The existing problems and future research highlights were also pointed out based on the above analysis. [Results] In previous studies, a variety of techniques have been used to estimate the gravity erosion on the Loess Plateau, each with intrinsic limitations and uncertainties. Presently, various methods, including onsite monitoring, onsite survey, field experiment and laboratory experiment, have been used to obtain the original data of gravity erosion on the gully sidewall covered with plants for analyzing the effects of vegetation on gravity erosion. A laboratory or field experiment may show the role of vegetation during the dynamic process of gravity erosion and the experiment is an effective way to study the micro-mechanism of gravity erosion. In contrast, the data of gravity erosion on a large scale can quickly obtained via remote sensing monitoring and the method may provide a reference for macro decision-making on soil and water conservation. Furthermore, the first-hand data observed via onsite monitoring or investigation from the real watershed may be used to testify the realizability of the result from the field or laboratory experiments. The previous studies show that soil erosion from the gully sidewall has not been obviously alleviated due to the serious gravity erosion although the ecological management has been greatly developed and the vegetation have been well restored in the small watersheds of the Loess Plateau. [Conclusions] The contribution of gravity erosion to sediment yield under the influence of vegetation and the complex relationship between the vegetation and gravity erosion need to be further explored. In the near future, to propose a new method is necessary in order to obtain the distribution information and development mechanism of gravity erosion and to evaluate the role of vegetation in conserving soil and water in the small watersheds on the Loess Plateau, China. Only has the mechanism of the gravity erosion been thoroughly understood, and then the theoretical framework can be constructed to study the gravity erosion in the area.

Key words： gravity erosion vegetation soil loss research methods Loess Plateau

收稿日期: 2021-07-30

PACS:

S157

基金资助:国家自然科学基金“多因素耦合作用下土质库岸崩滑过程机制研究”(51879032)

通讯作者: 徐向舟(1969-),男,教授,博士生导师。主要研究方向:水土保持与可持续发展。E-mail:xzxu@dlut.edu.cn E-mail: xzxu@dlut.edu.cn

作者简介: 高航(1986-),女,博士研究生。主要研究方向:水土保持。E-mail:gaohang525@mail.dlut.edu.cn

引用本文:

高航, 徐向舟, 李依杭. 黄土高原植被对重力侵蚀的作用机理[J]. 中国水土保持科学, 2022, 20(6): 137-142.
GAO Hang, XU Xiangzhou, LI Yihang. Retrospective study for the role of vegetation on the gravity erosion on the Loess Plateau. SSWC, 2022, 20(6): 137-142.

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http://journal12.magtechjournal.com/Jweb_stbc/CN/10.16843/j.sswc.2022.06.016 或 http://journal12.magtechjournal.com/Jweb_stbc/CN/Y2022/V20/I6/137

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