黄土区坡面侵蚀性径流标准与水沙关系分析

doi:10.16843/j.sswc.2022.06.002

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摘要径流侵蚀性是影响水沙行为的关键因素之一。有效辨识侵蚀性径流的水沙关系有利于深刻把握坡面水沙运行规律。选取3个径流指标,采用经验频率分析法,拟定黄土区坡面侵蚀性径流标准,分析不同尺度下侵蚀性与非侵蚀性事件的水沙关系。结果表明:1)坡面侵蚀性径流的一般参考标准为:径流历时>8min,最大流量>2.3dm³/s,次径流深>2.3mm,输沙模数>0.3kg/m²(相当于300t/km²);2)侵蚀性事件输沙模数主要受径流深控制,平均含沙量主要受最大流量影响,调节径流深的减沙效应较调节最大流量高8%;3)侵蚀性事件瞬时流量超过某一临界值(8~14dm³/s)时,瞬时含沙量呈现稳定状态(趋于490kg/m³);4)与非侵蚀性径流相比,侵蚀性径流的输沙能力增加2.9倍,产沙能力增加2.7倍。侵蚀性径流的输沙产沙能力更强,侵蚀性径流标准的拟定具有可行性,坡面径流调控应以实现侵蚀性径流向非侵蚀性径流的转化为导向。研究结果可为黄土区坡面典型径流事件的筛选提供借鉴。

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关键词 ：侵蚀性径流, 土壤侵蚀, 水沙关系, 事件时间尺度, 过程时间尺度

Abstract：[Background] When identifying erosive events, scholars primarily focused on erosive rainfall, but ignored the importance of runoff erosivity, which is one of the key factors influencing sediment flow behavior. Effectively identifying the relationship between runoff and sediment in erosive runoff is beneficial to a thorough understanding of the law of flow and sediment movement on slopes. Therefore, the standard for erosive runoff should be proposed to further reveal the mechanism of erosion from slope runoff. [Methods] The hydrological data used in the study was downloaded from National Earth System Science Data Center, National Science & Technology Infrastructure of China (http://www.geodata.cn). Erosive runoff standard was determined by the frequency analysis method. The procedures are: 1) M_s (area-specific sediment yield) was arranged in descending order of peak discharge or runoff depth; 2) summing the cumulative M_s in descending order, calculating the cumulative percentage of M_s to overall M_s of all runoff events; 3) optimal regression equations between cumulative percentage of M_s and peak discharge or runoff depth were acquired by regression analysis; 4) given that the cumulative percentage of M_s was 95%, the corresponding peak discharge and runoff depth were calculated through the optimal regression equations, then the erosive runoff standard was determined. Runoff-sediment relationship of erosive and non-erosive runoff events were analyzed at inter- and intra-events time scales through regression analysis method. [Results] 1) In this study, the general reference standards for erosive runoff are: ① The runoff duration is at least 8min; ② the peak discharge is above 2.3dm³/s; ③ the runoff depth is greater than 2.3mm; ④ the area-specific sediment yield is more than 0.3kg/m² (equivalent to 300t/km²). 2) The area-specific sediment yield by erosive runoff is mainly controlled by runoff depth whereas the mean sediment concentration is primarily driven by the peak discharge. On the basis of the erosive runoff standard, the sediment reduction benefit caused by regulating runoff depth is 8% higher than controlling peak discharge. 3) There is a power function relationship between instantaneous sediment concentration and instantaneous discharge in erosive events, and a stable tendency (approximately 490kg/m³) emerges in instantaneous sediment concentration when instantaneous discharge exceeds a critical value (8-14dm³/s). 4) There is a positive linear correlation between instantaneous sediment transport rate and instantaneous discharge in erosive events, and the positive linear correlation also appears between increment in area-specific sediment yield and increment in runoff depth. The sediment delivery capacity and sediment yield capacity of erosive runoff are 2.9 times and 2.7 times that of non-erosive runoff, respectively. [Conculsions] Compared with non-erosive runoff, the capacity of sediment transport and sediment yielding from erosive runoff is larger and the runoff-sediment relationship is more stable. Therefore, the proposal of erosive runoff standard is feasible in the present study, and then runoff regulation in slope should be orientated at the conversion from erosive runoff to non-erosive runoff.

Key words： erosive runoff soil erosion runoff-sediment relationship inter-event time scale intra-event time scale

收稿日期: 2021-10-18

PACS:

S157.1

基金资助:国家自然科学基金青年基金“侵蚀能量流视角下的小流域系统径流输沙尺度效应”(41807066),“基于热示踪法的地表-地下水瞬态交互流速场的量化研究”(41902251);国家自然科学基金面上项目“黄河流域专业村时空演化的内在机理研究”(42071220)

通讯作者: 张乐涛(1989-),男,博士,讲师。主要研究方向:土壤侵蚀和水土保持。E-mail:letao_20062006@126.com E-mail: letao_20062006@126.com

作者简介: 王清源(1996-),男,硕士研究生。主要研究方向:土壤侵蚀和水土保持。E-mail:qingyuanwang@henu.edu.cn

引用本文:

王清源, 张乐涛, 何梦真, 魏仪媛. 黄土区坡面侵蚀性径流标准与水沙关系分析[J]. 中国水土保持科学, 2022, 20(6): 8-16.
WANG Qingyuan, ZHANG Letao, HE Mengzhen, WEI Yiyuan. Erosive runoff standard and runoff-sediment relationship analysis on loess slope. SSWC, 2022, 20(6): 8-16.

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