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[1]Yang Chen,She Dongli,Huang Xuan.Runoff and sediment characteristics and transport processes at rainfall event scale in Kuye River Basin[J].Research of Soil and Water Conservation,2025,32(02):52-60.[doi:10.13869/j.cnki.rswc.2025.02.026]

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Runoff and sediment characteristics and transport processes at rainfall event scale in Kuye River Basin

Research of Soil and Water Conservation[ISSN 1005-3409/CN 61-1272/P] Volume: 32 Number of periods: 2025 02 Page number: 52-60 Column: Public date: 2025-01-20

Title:: Runoff and sediment characteristics and transport processes at rainfall event scale in Kuye River Basin

Author(s):: Yang Chen, She Dongli, Huang Xuan; (College of Agricultural Science and Engineering, Hohai University, Nanjing 211100, China)

Keywords:: rainfall event scale; transport processes; SSC-Q relationships; hysteresis analysis

CLC:: P333

DOI:: 10.13869/j.cnki.rswc.2025.02.026

Abstract:: [Objective]This study aims to provide significant scientific evidence for the management and regulation of water and sediment in the watersheds in coarse sand areas of the Loess Plateau by conducting an in-depth analysis of the characteristics of sediment and water dynamics and their transfer processes at the sub-rainfall event scale in the watersheds in coarse sand areas of the Loess Plateau. [Methods]Kuye River Basin in the coarse sand region of the Loess Plateau was selected as research site, water and sediment data from 160 rainfall events between 2006 and 2019 were collected. Variance analysis, sediment-rating curves, and hysteresis analysis were utilized to compare the runoff and sediment transport characteristics during sub-rainfall events in the Kuye River Basin and its sub-watersheds, to construct sediment-rating curves at the sub-rainfall event scale for each watershed, to analyze the spatial differences in the hysteresis relationship and hysteresis index of water and sediment, and to reveal the transfer processes of water and sediment in the Kuye River Basin at the sub-rainfall scale. [Results](1)There were no significant differences in runoff-related parameters among the four watersheds, but significant differences were observed in sediment-related parameters.(2)The Xinmiao watershed in the eastern upper reaches of the Kuye River showed a strong correlation between runoff and sediment, with the parameter(a)indicating the degree of external anthropogenic interference being the highest, while the Wangdaohengta watershed in the western upper reaches had a low sediment concentration and weak runoff-sediment correlation, with the parameter(b)representing the river's own sediment transport capacity being the highest.(3)The primary hysteresis pattern in the Xinmiao, Wangdaohengta and Wenjichuan watersheds was anti-clockwise, indicating that sediment originated from the upper reaches and the average value of the high sediment concentration Hysteresis Indexi(HI)was mostly negative. In contrast, the Shenmu Watershed's primary hysteresis pattern was 8-shaped pattern, indicating that sediment sources were relatively close to the watershed outlet, and the average HI value for high sediment concentration rainfall events was mostly positive. [Conclusion]The nested watersheds of the Kuye River exhibit significant spatial differences in water and sediment changes, and the sediment transport process is complex. The hysteresis patterns in different sub-watersheds reveal the spatial heterogeneity of sediment sources and transport mechanisms at rainfall event scale.

References:: [1]Nie J S, Stevens T, Rittner M, et al. Loess Plateau storage of northeastern Tibetan Plateau-derived Yellow River sediment[J]. Nature Communications, 2015,6(1):8511.
[2]史志华,刘前进,张含玉,等.近十年土壤侵蚀与水土保持研究进展与展望[J].土壤学报,2020,57(5):1117-1127.
Shi Z H, Liu Q J, Zhang H Y, et al. Study on soil erosion and conservation in the past 10 years:progress and prospects[J]. Acta Pedologica Sinica, 2020,57(5):1117-1127.
[3]Guo W X, Sang Y, Hu J W, et al. Characteristics and attribution analysis of runoff and sediment evolution in the Wei River mainstream, China[J]. Journal of Water and Climate Change, 2023,14(7):2432-2447.
[4]康靖羚,丁文峰,韩昊宇,等.不同时间尺度岔巴沟流域水沙关系变化[J].水土保持研究,2021,28(5):81-87.
Kang J L, Ding W F, Han H Y, et al. Relationship between runoff and sediment on different time scales in Chabagou watershed[J]. Research of Soil and Water Conservation, 2021,28(5):81-87.
[5]刘春月,信忠保,秦瑞杰,等.1986—2018年黄土丘陵区典型小流域不同水文年水沙变化[J].水土保持研究,2024,31(1):126-135.
Liu C Y, Xin Z B, Qin R J, et al. Variation of runoff and sediment of the typical watershed in Loess Hilly Region in the different hydrological years during the period from 1986 to 2018[J]. Research of Soil and Water Conservation, 2024,31(1):126-135.
[6]Xu Z, Zhang S H, Zhou Y, et al. Characteristics of watershed dynamic sediment delivery based on improved RUSLE model[J]. Catena, 2022,219:106602.
[7]Wei W, Chen L D, Fu B J, et al. Responses of water erosion to rainfall extremes and vegetation types in a loess semiarid hilly area, NW China[J]. Hydrological Processes, 2009,23(12):1780-1791.
[8]Wang H, Chen W X, Zhou M, et al. Runoff and sediment characteristics of a typical watershed after continuous soil erosion control in the red soil region of Southern China[J]. Catena, 2023,233:107484.
[9]董玉婷,穆兴民,王双银,等.产流及其研究进展[J].华北水利水电大学学报:自然科学版,2022,43(2):21-29.
Dong Y T, Mu X M, Wang S Y, et al. Runoff generation and its research progress[J]. Journal of North China University of Water Resources and Electric Power:Natural Science Edition,2022,43(2):21-29.
[10]史志华,宋长青.土壤水蚀过程研究回顾[J].水土保持学报,2016,30(5):1-10.
Shi Z H, Song C Q. Water erosion processes:a historical review[J]. Journal of Soil and Water Conservation, 2016,30(5):1-10.
[11]Jansson M B. Determining sediment source areas in a tropical river basin, Costa Rica[J]. Catena, 2002,47(1):63-84.
[12]Collins A L, Blackwell M, Boeckx P, et al. Sediment source fingerprinting:benchmarking recent outputs, remaining challenges and emerging themes[J]. Journal of Soils and Sediments, 2020,20(12):4160-4193.
[13]De Girolamo A M, Ricci G F, Abdelwahab O M M, et al. Suspended sediment transport in Mediterranean streams:monitoring and load estimation[J]. Water, 2023,15(15):2715.
[14]Tilahun A K, Verstraeten G, Chen M, et al. Temporal and spatial variability of suspended sediment rating curves for rivers draining into the Ethiopian Rift Valley[J]. Land Degradation & Development, 2023,34(2):478-492.
[15]王赫,陈文祥,李会光,等.南方红壤区典型水土流失治理小流域的洪水径流泥沙特征[J].农业工程学报,2023,39(15):86-93.
Wang H, Chen W X, Li H G, et al. Runoff and sediment characteristics of flood events in a typical soil and water conservation watershed in the red soil region of southern China[J]. Transactions of the Chinese Society of Agricultural Engineering, 2023,39(15):86-93.
[16]Malutta S, Kobiyama M, Chaffe P L B, et al. Hysteresis analysis to quantify and qualify the sediment dynamics:state of the art[J]. Water Science and Technology, 2020,81(12):2471-2487.
[17]Smith H G, Dragovich D. Interpreting sediment delivery processes using suspended sediment-discharge hysteresis patterns from nested upland catchments, south-eastern Australia[J]. Hydrological Processes, 2009,23(17):2415-2426.
[18]刘强,蔡学娅,刘君怡,等.黄河中游窟野河流域水沙关系变化特征及其成因分析[J].水土保持研究,2022,29(4):68-74.
Liu Q, Cai X Y, Liu J Y, et al. Variation characteristics and causes of runoff-sediment relationship in Kuye river basin in the middle reaches of the Yellow River[J]. Research of Soil and Water Conservation, 2022,29(4):68-74.
[19]Tian P, Feng J H, Zhao G J, et al. Rainfall, runoff, and suspended sediment dynamics at the flood event scale in a Loess Plateau watershed, China[J]. Hydrological Processes, 2022,36(2):e14486.
[20]孟泽坤,王彬, Daniel Moriasi.次降雨时空分布对流域产流产沙的影响[J].中国水土保持科学(中英文),2023,21(4):69-78.
Meng Z K, Wang B, Daniel M. Effects of the spatio-temporal pattern of single storm on the runoff and sediment yield at watershed scale[J]. Science of Soil and Water Conservation, 2023,21(4):69-78.
[21]Lloyd C E M, Freer J E, Johnes P J, et al. Using hysteresis analysis of high-resolution water quality monitoring data, including uncertainty, to infer controls on nutrient and sediment transfer in catchments[J]. Science of the Total Environment, 2016,543:388-404.
[22]潘雅文,马文龙,潘庆宾,等.流域侵蚀输沙空间尺度效应及其影响因素研究进展[J].水土保持研究,2022,29(3):88-97,105.
Pan Y W, Ma W L, Pan Q B, et al. Review of the scale effects of soil erosion and sediment delivery and their influencing factors[J]. Research of Soil and Water Conservation, 2022,29(3):88-97,105.
[23]Ni J P, Wei C F, D T. Effects of spatial scale on the quantitative estimation of soil erosion[J]. Acta Ecologica Sinica, 2005,25(8):2061-2067.
[24]Pulley S, Collins A L. Soil erosion, sediment sources, connectivity and suspended sediment yields in UK temperate agricultural catchments:discrepancies and reconciliation of field-based measurements[J]. Journal of Environmental Management, 2024,351:119810.
[25]Sun P C, Wu Y P, Gao J N, et al. Shifts of sediment transport regime caused by ecological restoration in the middle Yellow River basin[J]. Science of the Total Environment, 2020,698:134261.

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Last Update: 2025-01-20