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.
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.
曹斌挺, 焦菊英, 王志杰, 等. 2013年延河流域特大暴雨下的滑坡特征[J]. 水土保持研究, 2015, 22(6): 103. CAO Binting, JIAO Juying, WANG Zhijie, et al. Characteristic of landslide under the extreme rainstorm in 2013 in the Yanhe Basin[J]. Research of Soil and Water Conservation, 2015, 22(6): 103.
[2]
朱同新, 蔡强国, 张勋昌. 王家沟流域重力侵蚀的时空分布规律[C]//山西省水土保持科学研究所, 中国科学院国家计划委员会地理研究所, 加拿大多伦多大学地理系. 晋西黄土高原土壤侵蚀规律实验研究文集. 北京: 水利电力出版社, 1990: 116. ZHU Tongxin, CAI Qiangguo, ZHANG Xunchang. Temporal and spatial variation of gravitational erosion in Wangjiagou Gully [C]//Sino-Canadian Symposium of Experimental Researches on the Law of Soil Erosion in the Loess Plateau Region, Western Shanxi (edited by Shanxi Science Institute of Soil and Water Conservation, Geography Institute of the State Planning Commission and Chinese Academy of Sciences, and Geography Department of the University of Toronto (Canada)). Beijing: Water & Power Press, 1990: 116.
[3]
姚文艺. 新时代黄河流域水土保持发展机遇与科学定位[J]. 人民黄河, 2019, 41(12): 1. YAO Wenyi. Development opportunity and scientific positioning of soil and water conservation of the Yellow River in the New Era [J]. Yellow River, 2019, 41(12): 1.
[4]
IVANOV V, LONGONI L, FERRARIO M, et al. Applicability of an interferometric optical fibre sensor for shallow landslide monitoring-experimental tests [J]. Engineering Geology, 2021, 288: 106128.
[5]
张伟琪, 王利, 曲轩宇. 基于测量机器人的黄土滑坡变形监测及结果分析[J]. 测绘工程, 2019, 28(3): 66. ZHANG Weiqi, WANG Li, QU Xuanyu. Deformation monitoring and result analysis of loess landslide based on geo-robot [J]. Engineering of Surveying and Mapping, 2019, 28(3): 66.
[6]
杨吉山, 姚文艺, 王玲玲. 黄土沟道重力侵蚀规律及机理研究[J]. 人民黄河, 2014, 36(6): 93. YANG Jishan, YAO Wenyi, WANG Lingling. Study on the regularity and mechanism of gravity erosion in the loess gully [J]. Yellow River, 2014, 36(6): 93.
[7]
XU Xiangzhou, ZHU Tongxin, ZHANG Hongwu, et al. Experimental erosion: Theory and practice of soil conservation experiments [M]. Beijing & Singapore: Science Press and Springer Nature, 2020: 1.
[8]
柯奇画, 张科利. 我国人工降雨侵蚀相关试验的研究进展回顾[J]. 中国水土保持科学, 2018, 16(2): 134. KE Qihua, ZHANG Keli. A review on the erosion-related researches by simulated rainfall experiments in China [J]. Science of Soil and Water Conservation, 2018, 16(2): 134.
[9]
XU Xiangzhou, LIU Zhenyi, XIAO Peiqing, et al. Gravity erosion on the steep loess slope: Behavior, trigger and sensitivity [J]. Catena, 2015, 135: 231.
[10]
GUO Wenzhao, XU Xiangzhou, WANG Wenlong, et al. A measurement system applicable for landslide experiments in the field [J]. Review of Scientific Instruments, 2016, 87(4): 44501.
[11]
RAHARDJO H, LEE T T, LEONG E C, et al. Response of a residual soil slope to rainfall [J]. Canadian Geotechnical Journal, 2005, 42(2): 340.
[12]
GAREL E, MARC V, RUY S, et al. Large scale rainfall simulation to investigate infiltration processes in a small landslide under dry initial conditions: The Draix hillslope experiment [J]. Hydrological Processes, 2012, 26(14): 2171.
[13]
张霞. 黄土区地貌与植被格局的侵蚀动力过程试验研究[D]. 西安: 西安理工大学, 2018: 17. ZHANG Xia. Experimental study on erosion dynamics process of geomorphology and vegetation pattern in Loess Plateau [D]. Xi'an: Xi'an University of Technology, 2018: 17.
[14]
王照财, 赵其华, 韩俊, 等. 台风作用下植被对斜坡稳定性影响的物理模拟[J]. 自然灾害学报, 2013, 22(4): 145. WANG Zhaocai, ZHAO Qihua, HAN Jun, et al. Physical modeling of the effect of vegetation on slope stability under typhoon [J]. Journal of Natural Disasters, 2013, 22(4): 145.
[15]
GAO Hang, XU Xiangzhou, ZHANG Hongwu, et al. How effective is vegetation in reducing gravity erosion on loess gully sidewall under intense rainfalls? [J]. Land Degradation & Development, 2020, 31(17): 2605.
[16]
陈攀攀, 常宏涛, 毕华兴, 等. 黄土高塬沟壑区典型小流域土地利用变化及其对水土流失的影响[J]. 中国水土保持科学, 2011, 9(2): 57. CHEN Panpan, CHANG Hongtao, BI Huaxing, et al. Land use change and its effects on soil and water loss in typical small watershed of Loess Plateau gully region [J]. Science of Soil and Water Conservation, 2011, 9(2): 57.
[17]
ZHAO Chunhong, GAO Jian'en, HUANG Yuefei, et al. Effects of vegetation stems on hydraulics of overland flow under varying water discharges [J]. Land Degradation & Development, 2016, 27(3): 748.
[18]
陈晓清, 崔鹏, 韦方强. 良好植被区泥石流防治初探[J]. 山地学报, 2006, 24(3): 333. CHEN Xiaoqing, CUI Peng, WEI Fangqiang. Study of control debris flow in high-covered vegetation region [J]. Journal of Mountain Science, 2006, 24(3): 333.
[19]
韩勇, 郑粉莉, 徐锡蒙, 等. 子午岭林区浅层滑坡侵蚀与植被的关系:以富县"7·21"特大暴雨为例[J]. 生态学报, 2016, 36(15): 4635. HAN Yong, ZHENG Fenli, XU Ximeng, et al. Relationship between shallow landslide erosion and vegetation in the Ziwuling forest area: A case study of the "7·21" disaster in Fuxian county [J]. Acta Ecologica Sinica, 2016, 36(15): 4635.
[20]
黄河水利委员会黄河中游治理局编著. 黄河志·卷八·黄河水土保持志[M]. 郑州: 河南人民出版社, 1993:57. Edited by Management Bureau of the Middle Yellow River of the Yellow River Conservancy Commission. Chronicles of soil and water conservation in the Yellow River basin (Volume 8 of the Yellow River Chronicles) [M]. Zhengzhou: Henan People's Publishing House, 1993: 57.
[21]
徐雪良. 韭园沟流域沟间地、沟谷地来水来沙量的研究[J]. 中国水土保持, 1987(8): 23. XU Xueliang. Study on runoff and sediment amounts in gully land and gully land in Jiuyuangou Watershed [J]. Soil and Water Conservation in China, 1987(8): 23.
[22]
焦菊英, 王志杰, 魏艳红, 等. 延河流域极端暴雨下侵蚀产沙特征野外观测分析[J]. 农业工程学报, 2017, 33(13): 159. JIAO Juying, WANG Zhijie, WEI Yanhong, et al. Characteristics of erosion sediment yield with extreme rainstorms in Yanhe Watershed based on field measurement [J]. Transactions of the CSAE, 2017, 33(13): 159.
[23]
许炯心. 黄土高原的高含沙水流侵蚀研究[J]. 土壤侵蚀与水土保持学报, 1999, 5(1): 27. XU Jiongxin. Erosion and sediment yield of hyperconcentrated flows on Loess Plateau [J]. Journal of Soil Erosion and Soil and Water Conservation, 1999, 5(1): 27.