典型降雨事件下流域磷流失特征与影响因素

doi:10.11988/ckyyb.20240132

raybet体育在线院报 ›› 2025, Vol. 42 ›› Issue (5): 81-87.DOI: 10.11988/ckyyb.20240132

典型降雨事件下流域磷流失特征与影响因素

刘晓荣¹(), 杜新忠², 刘新茹², 韩玉国¹(), 安妙颖², 雷秋良², 刘宏斌²

¹ 北京林业大学水土保持学院,北京 100083
² 农业农村部面源污染控制重点实验室/北京昌平土壤质量国家野外科学观测研究站/北方干旱半干旱耕地高效利用全国重点实验室,中国农业科学院农业资源与农业区划研究所,北京 100081

收稿日期:2024-02-14 修回日期:2024-05-13 出版日期:2025-05-01 发布日期:2025-05-01
通信作者:
韩玉国(1972-),男,内蒙古通辽人,教授,博士,主要从事水土保持与荒漠化防治、流域面源污染治理、水土资源高效利用等研究。E-mail:yghan@bjfu.edu.cn
作者简介:
刘晓荣(1999-),女,河北南宫人,硕士研究生,研究方向为流域面源污染模拟与关键源区识别。E-mail: lxr990317@163.com
基金资助:
国家重点研发计划项目(2022YFC3204001); 国家自然科学基金青年基金项目(42107076); 国家自然科学基金区域联合重点基金项目(U20A20114)

Characteristics and Influencing Factors of Phosphorus Loss in Watersheds during Typical Rainfall Events

LIU Xiao-rong¹(), DU Xin-zhong², LIU Xin-ru², HAN Yu-guo¹(), AN Miao-ying², LEI Qiu-liang², LIU Hong-bin²

¹ School of Soil and Water Conservation, Beijing Forestry University,Beijing 100083, China
² Key Laboratory of Non-point Source Pollution Control, Ministry of Agriculture and Rural Affairs/Changping Soil Quality National Observation and Research Station/State Key Laboratory of Efficient Utilization of Arid and Semi-arid Arable Land in Northern China, Institute of Agricultural Resources and Regional Planning, Chinese Academy of Agricultural Sciences, Beijing 100081, China

Received:2024-02-14 Revised:2024-05-13 Published:2025-05-01 Online:2025-05-01

摘要/Abstract

摘要： 为了解典型降雨事件下流域磷流失特征及其影响因素,于2022年和2023年汛期,在流域出口监测了5场不同强度的降雨事件,共采集样品265个并测定总磷(TP)、总溶解态磷(DP)、颗粒态磷(PP)浓度,分析不同降雨事件中磷浓度输出过程和影响因素,结合滞后分析揭示磷流失水文过程。结果表明:①不同类型降雨事件中TP、PP浓度与流量变化趋势一致。②降雨总量、降雨历时,洪峰流量、最大30 min降雨强度与磷浓度之间呈正相关,前期降雨指数与磷浓度呈负相关。③降雨过程中流失的磷以颗粒态为主,占比67%~93%。④TP、PP和DP浓度与流量之间没有统一的滞后效应;TP和PP的滞后效应一致,流域磷来自地表径流。

关键词: 典型降雨, 滞后效应, 磷流失, 影响因素, 磷污染负荷, 凤羽河流域

Abstract:

[Objective] Surface runoff and soil erosion during rainfall events are the main drivers of phosphorus (P) loss in watersheds, particularly during the rainy season when a few key heavy rainfall events can dominate annual phosphorus load outputs. However, the characteristics of phosphorus loss, influencing factors, and lag effects during different intensities of typical rainfall events in the rainy season remain to be further explored. This study aims to understand the characteristics and influencing factors of phosphorus loss under various magnitudes of typical rainfall events and to analyze the phosphorus loss process during dominant rainfall events. [Methods] During the 2022 and 2023 rainy seasons, five rainfall events (E1-E5) of varying intensities were monitored at the outlet of the Fengyu River sub-watershed, a typical agricultural watershed in the Erhai Lake Basin, Yunnan Province. The rainfall types for events E1-E5 were moderate rain, light rain, moderate rain, heavy rain, and heavy rain. A total of 265 water samples were collected to determine three forms of phosphorus: total phosphorus (TP), total dissolved phosphorus (DP), and particulate phosphorus (PP). Redundancy analysis was used to explore the relationships between phosphorus concentrations/loads and rainfall-runoff characteristics, identifying the key factors influencing phosphorus output and its process. Lag analysis was applied to reveal the hydrological processes behind phosphorus loss. [Results] The results indicated that: (1) The trends of TP and PP concentrations were consistent with flow changes across different types of rainfall events. (2) Total rainfall, rainfall duration, peak flow, and maximum 30-minute rainfall intensity were positively correlated with phosphorus concentrations, while antecedent rainfall index was negatively correlated. (3) Particulate phosphorus dominated the phosphorus loss during rainfall events, accounting for 67%-93% of the total. (4) There was no uniform lag effect between TP, PP, and DP concentrations and discharge. TP and PP shared similar lag effects, indicating that phosphorus primarily originated from surface runoff. [Conclusion] Changes in phosphorus concentrations during rainfall events are influenced by rainfall magnitude, intensity, and antecedent soil conditions. Concentrations and loads of all phosphorus forms were strongly correlated with rainfall duration, total rainfall, peak flow, and 30-minute maximum intensity (I30). The relationship between nutrient concentration and discharge is jointly determined by total rainfall, rainfall duration, antecedent conditions, and hydrological regime. By identifying the characteristics of phosphorus output under various rainfall events during the rainy season, this study provides insights into phosphorus load contributions and supports the control of phosphorus pollution and eutrophication in watershed water bodies.

Key words: typical rainfall events, lag effect, phosphorus loss, influencing factors, phosphorus pollution load, Fengyu River watershed

中图分类号:

X52水体污染及其防治

刘晓荣, 杜新忠, 刘新茹, 韩玉国, 安妙颖, 雷秋良, 刘宏斌. 典型降雨事件下流域磷流失特征与影响因素[J]. raybet体育在线院报, 2025, 42(5): 81-87.

LIU Xiao-rong, DU Xin-zhong, LIU Xin-ru, HAN Yu-guo, AN Miao-ying, LEI Qiu-liang, LIU Hong-bin. Characteristics and Influencing Factors of Phosphorus Loss in Watersheds during Typical Rainfall Events[J]. Journal of Changjiang River Scientific Research Institute, 2025, 42(5): 81-87.

图/表 8

图1 洱海流域和凤羽河流域的DEM

Fig.1 DEM map of Erhai Lake Basin and Fengyu River Basin

表1 降水事件特征及水文条件

Table 1 Characteristics of precipitation events and hydrological conditions

降雨事件	降雨量/mm	降雨历时/h	降雨类型	I₃₀/ (mm·h^-1)	API/ mm	最大雨强/ (mm·h^-1)	平均雨强/ (mm·h^-1)	洪峰流量/ (m³·s^-1)	平均流量/ (m³·h^-1)	总流量/ (10⁶ m³)	洪峰滞时/h
E1	35.8	173.0	中雨	12.4	17.07	8.6	0.21	9.87	5.13	3.20	0.5
E2	2.2	91.0	小雨	2.8	20.53	1.8	0.02	5.65	4.47	1.47	6.0
E3	14.0	48.5	中雨	7.6	8.51	7.2	0.29	3.43	2.52	0.44	0.5
E4	193.0	540.0	大雨	31.6	13.91	19.4	0.36	25.73	7.79	15.16	3.5
E5	46.0	166.0	大雨	8.0	21.27	7.0	0.27	17.16	6.20	4.12	12.0

表2 5场降雨事件中流量及不同形态磷浓度变化范围

Table 2 Variation ranges of flow and concentrations of phosphorus of different forms during five rainfall events

事件	流量Q/ (m³·s^-1)	TP浓度/ (mg·L^-1)	DP浓度/ (mg·L^-1)	PP浓度/ (mg·L^-1)
E1	3.83~9.87	0.26~8.20	0.03~0.29	0.18~8.05
E2	3.54~5.65	0.24~2.32	0.03~0.17	0.09~2.15
E3	1.25~3.43	0.17~5.44	0.05~0.52	0.12~5.27
E4	2.79~25.73	0.17~24.6	0.02~0.48	0.03~24.27
E5	3.48~17.35	0.27~2.72	0.13~0.43	0.02~2.53

图2 5场降雨事件的流量及TP、DP、PP浓度动态变化

Fig.2 Dynamic variations of flow,TP,DP,and PP concentrations duringfive rainfall events

图3 不同形态磷输出浓度、负荷与降雨径流特征冗余分析结果

Fig.3 Redundancy analysis results of output concentration, and load of different phosphorus forms and rainfall runoff characteristics

图4 5场降雨事件中PP通量、DP通量占比

Fig.4 Proportions of PP and DP in five rainfall events

图5 降雨事件E1、E2、E3和E5中的TP浓度和PP浓度滞后效应

Fig.5 Lag effect of TP concentration in rainfall events E1, E2, E3, and E5

图6 降雨事件E4中的TP浓度和PP浓度滞后效应

Fig.6 Lag effect of TP concentration in rainfall event E4

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典型降雨事件下流域磷流失特征与影响因素

Characteristics and Influencing Factors of Phosphorus Loss in Watersheds during Typical Rainfall Events

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