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【目的】为防控面源污染对水环境的不良影响,精准解析降水-土壤-作物系统中面源污染动态形成机制与协同防控策略具有重要作用。【方法】设计多维度动态对比模拟降水试验,通过控制作物类型(小麦和玉米)、生育期(生长期和成熟期)及管理措施(施肥和未施肥)三个关键变量,结合高频径流监测与土壤理化分析量化不同情景径流污染特征差异。【结果】径流在降水2 h后形成且污染物浓度随历时衰减;85 cm株高玉米田径流、铵氮、总氮、硝态氮和总磷浓度较小麦田分别高210.3%、38.0%、188.5%、275.4%和128.1%;株高200 cm玉米田径流铵氮、总氮、硝态氮和总磷流失通量较80 cm株高分别下降68.8%、79.3%、88.5%和62.5%。小麦生长期施肥使径流COD、总氮、硝态氮和总磷浓度较未施肥分别增加43.9%、15.9%、57.5%、56.1%,玉米生长期施肥使径流COD、铵氮、总氮和硝态氮浓度较未施肥分别下降18.2%、68.2%、25.6%和60.7%。【结论】径流污染触发需满足临界降雨强度且污染物通量随降雨历时显著衰减,表层土壤存在“冲刷极限”效应。玉米成熟期强化冠层截留与根系吸收使氮磷流失通量较80 cm株高时下降。
Abstract:[Objective]To mitigate the adverse impacts of non-point source pollution on the aquatic environment, it is crucial to accurately elucidate the dynamic formation mechanisms of such pollution and the synergistic control strategies within the precipitation-soil-crop system.[Methods]A multi-dimensional dynamic comparative precipitation simulation experiment was designed by controlling three key variables: crop type(wheat and maize), growth stage(growing and mature), and management practice(fertilized and unfertilized). Differences in runoff pollution characteristics under different scenarios were quantified through high-frequency runoff monitoring and soil physicochemical analysis.[Results]Runoff formed 2 hours after precipitation, and pollutant concentrations decreased over time. In maize fields with a plant height of 85 cm, runoff concentrations of chemical oxygen demand(COD), ammonium nitrogen(NH4~+-N), total nitrogen(TN), nitrate nitrogen(NO3~--N), and total phosphorus(TP) were 210.3%, 38.0%, 188.5%, 275.4%, and 128.1% higher, respectively, than those in wheat fields. For maize at 200 cm plant height, runoff fluxes of NH4~+-N, TN, NO3~--N, and TP decreased by 68.8%, 79.3%, 88.5%, and 62.5%, respectively, compared to those at 80 cm plant height. Fertilization during the wheat growing stage increased runoff concentrations of COD, TN, NO3~--N, and TP by 43.9%, 15.9%, 57.5%, and 56.1%, respectively, compared to unfertilized plots. In contrast, fertilization during the maize growing stage reduced runoff concentrations of COD, NH4~+-N, TN, and NO3~--N by 18.2%, 68.2%, 25.6%, and 60.7%, respectively, compared with unfertilized plots.[Conclusion]Runoff pollution is triggered only when rainfall intensity exceeds a critical threshold, and pollutant fluxes show a pronounced decay over the rainfall duration, reflecting a “scouring threshold” effect in the surface soil. Compared to the 80 cm plant height stage, enhanced canopy interception and root uptake significantly reduced nitrogen and phosphorus loss fluxes during the mature maize stage.
[1] SERRA J,MARINHEIRO J,MARQUES-DOS-SANTOS C S C,et al.Evaluation of global research on agricultural nitrogen pollution between 1990 and 2023:Challenges for more efficacy and equity[J].Environmental Science & Policy,2026,176:104312.
[2] 蒋昀耕,张静,卢少勇,等.我国农村生活污水与农田退水面源氮磷污染生态净化技术现状与研究进展[J].农业资源与环境学报,2024,41(3):688-696.JIANG Y G,ZHANG J,LU S Y,et al.Present situation and progress of ecological purification technology for nitrogen and phosphorus pollution from rural domestic sewage and farmland water surface in China[J].Journal of Agricultural Resources and Environment,2024,41(3):688-696.
[3] RATHORE R,BAKSHI B R,KODAMANA H,et al.Multi-objective optimization of crop land allocation for sustainability within the food-energy-water-land-fertilizer (FEWLF) nexus[J].Computers & Chemical Engineering,2025,201:109207.
[4] 于滢,姬广兴,陈轶楠,等.北方集约化农区农业氮素面源污染模拟及动因分析[J].环境科学,2025,46(5):2783-2792.YU Y,JI G X,CHEN Y N,et al.Simulation and motivation analysis of agricultural nitrogen non-point source pollution in north intensive farming area[J].Environmental Science,2025,46(5):2783-2792.
[5] 刘晋涛,余香英,王平平,等.漠阳江流域降雨径流面源污染下总磷变化特征研究[J].环境污染与防治,2025,47(3):67-73.LIU J T,YU X Y,WANG P P,et al.Research on the variation characteristics of total phosphorus under rainfall runoff non-point source pollution in the Moyang River Basin[J].Environmental Pollution & Control,2025,47(3):67-73.
[6] ZHANG S,ZHANG L L,MENG Q Y,et al.Evaluating agricultural non-point source pollution with high-resolution remote sensing technology and SWAT model:A case study in Ningxia Yellow River Irrigation District,China[J].Ecological Indicators,2024,166:112578.
[7] 刘连华,欧阳威,白艳,等.基于田-沟-塘系统优化的稻作流域氮素面源污染减排潜力评估[J].中国环境科学,2025,45(5):2693-2699.LIU L H,OUYANG W,BAI Y,et al.Evaluation on the reduction potential of diffuse nitrogen pollution in paddy field watersheds based on field-ditch-pond system optimization[J].China Environmental Science,2025,45(5):2693-2699.
[8] ZHAO Y F,HU Z J,LU Y P,et al.Facilitating mitigation of agricultural non-point source pollution and improving soil nutrient conditions:The role of low temperature co-pyrolysis biochar in nitrogen and phosphorus distribution[J].Bioresource Technology,2024,394:130179.
[9] JAVED A,ARNILLAS C A,SAHA R,et al.Striking a balance between food security and water quality:A modelling analysis of agricultural management practices in mitigating non-point source phosphorus pollution[J].Science of the Total Environment,2025,974:179135.
[10] TIAN Y S,SHEN J,FENG J M,et al.Research advancements on agricultural non-point source pollution in major lake and reservoir watersheds of China:Status,sources,monitoring,and prospects[J].Ecological Indicators,2025,178:113981.
[11] 王俊力,付子轼,乔红霞,等.河套灌区种植业面源污染风险空间格局识别:以内蒙古巴彦淖尔市五原县为例[J].环境工程技术学报,2025,15(3):915-923.WANG J L,FU Z S,QIAO H X,et al.Identification of spatial pattern of non-point source pollution risk from planting industry in Hetao Irrigation Area:A case study of Wuyuan County in Bayannur,Inner Mongolia[J].Journal of Environmental Engineering Technology,2025,15(3):915-923.
[12] 逯颖,张建辉,李文君,等.长江经济带农业面源总磷污染时空特征分析[J].农业环境科学学报,2024,43(12):2752-2764.LU Y,ZHANG J H,LI W J,et al.Analysis on spatiotemporal characteristics of total phosphorus of agricultural non-point source pollution in the Yangtze River Economic Belt[J].Journal of Agro-Environment Science,2024,43(12):2752-2764.
[13] DUPAS R,FAUCHEUX M,SENGA KIESSÉ T,et al.High-intensity rainfall following drought triggers extreme nutrient concentrations in a small agricultural catchment[J].Water Research,2024,264:122108.
[14] 陈诚,怀红燕,吴阿娜,等.平原河网地区农田面源污染月尺度入河系数精准测算方法[J].农业环境科学学报,2024,43(12):2838-2847.CHEN C,HUAI H Y,WU E N,et al.Method of monitoring and calculating monthly export coefficient of farmland non-point source pollution at outlets into rivers in the plain river network areas[J].Journal of Agro-Environment Science,2024,43(12):2838-2847.
[15] BERGER N K,KOLLMANN J,TEIXEIRA L H.Native plant communities designed for infiltration swales can tolerate urban heat,flooding,and pollution[J].Basic and Applied Ecology,2026,90:89-98.
[16] MIN M,LI H,MA T,et al.Will agricultural land scale management aggravate non-point source pollution-Chaohu Lake Basin,China as a case study[J].Applied Geography,2023,158:103056.
[17] LIU R M,ZHANG P P,WANG X J,et al.Assessment of effects of best management practices on agricultural non-point source pollution in Xiangxi River watershed[J].Agricultural Water Management,2013,117:9-18.
[18] YANG R Z,FENG T J,WANG B,et al.Response of soil erosion and non-point source pollution to different rainfall,vegetation and land preparation measures in Miyun reservoir area during 2010—2023[J].International Soil and Water Conservation Research,2025,13(4):892-908.
[19] HUANG J J,LIN X J,WANG J H,et al.The precipitation driven correlation based mapping method (PCM) for identifying the critical source areas of non-point source pollution[J].Journal of Hydrology,2015,524:100-110.
[20] HE F,LIU F K,LI S H,et al.A critical review of soil pollution sources and advances in the remediation of arsenic-contaminated soil[J].Ecotoxicology and Environmental Safety,2025,302:118504.
[21] CHANG L,JU T H,LIANG K Y,et al.Biochar-influenced solubilization and mineralization mechanisms of phosphorus in saline-sodic soils[J].Soil Biology and Biochemistry,2025,209:109890.
[22] MCKENNA B A,KOPITTKE P M,BELL M J,et al.Phosphorus availability and speciation in the fertosphere of three soils over 12 months[J].Geoderma,2024,447:116913.
[23] 杨世琦,颜鑫.基于农作物施肥量视角的区域尺度农田面源污染风险评价研究[J].中国农业大学学报,2023,28(2):147-159.YANG S Q,YAN X.Risk assessment of non-point sources pollution in farmland based on main crop fertilizer application rate[J].Journal of Chine Agricultural University,2023,28(2):147-159.
[24] 陈建生,徐培智,唐拴虎,等.秋播甜玉米氮磷钾营养特点及施肥措施对其影响研究[J].中国农学通报,2008,(11):272-277.CHEN J S,XU P Z,TANG S H,et al.Characteristics of NPK nutrition and as affected by fertilization for fall-sowing sweet corn[J].Chinese Agricultural Science Bulletin,2008,24(11):272-277.
[25] 勾宇春,王宗抗,张志鹏,等.植物根际促生菌作用机制研究进展[J].应用与环境生物学报,2023,29(2):495-506.GOU Y C,WANG Z K,ZHANG Z P,et al.Advance in role mechanisms of plant growth-promoting rhizobacteria[J].Chinese Journal of Applied & Environmental Biology,2023,29(2):495-506.
[26] 吴诗剑,黄海波,张旭,等.典型都市农业村域果园土壤磷素的渗漏特征研究:以上海南汇新场镇果园村为例[J].科技通报,2013,29(11):195-198.WU S J,HUANG H B,ZHANG X,et al.Study on the leakage characteristics of soil phosphorous in an orchard in the urban agricultural region of Shanghai[J].Bulletin of Science and Technology,2013,29(11):195-198.
[27] ZHANG N,ZHANG Q,LI Y Q,et al.Effect of groundcovers on reducing soil erosion and non-point source pollution in citrus orchards on red soil under frequent heavy rainfall[J].Sustainability,2020,12(3):1146.
[28] LYU S Q,YANG T,LI J,et al.Soil mulching enhanced maize canopy ammonia flux in contrast mitigating field ammonia emission [J].European Journal of Agronomy,2026,175:128002.
[29] 施卫明,王远,闵炬.中国农业面源污染防控研究进展与工程案例[J].土壤学报,2023,60(5):1309-1323.SHI W M,WANG Y,MIN J.Progress in research and engineering application cases of agricultural non-point source pollution control in China[J].Acta Pedologica Sinica,2023,60(5):1309-1323.
[30] AKHTAR S,HUSSAIN M I,KHAN Z I,et al.Wastewater irrigation elevates chromium uptake in cereal crops:Bioaccumulation dynamics and carcinogenic risk assessment in a semi-arid agroecosystems[J].Agricultural Water Management,2025,321:109906.
[31] HUANG S,LYU W S,BLOSZIES S,et al.Effects of fertilizer management practices on yield-scaled ammonia emissions from croplands in China:A meta-analysis[J].Field Crops Research,2016,192:118-125.
[32] 陶园,徐静,任贺靖,等.黄河流域农业面源污染时空变化及因素分析[J].农业工程学报,2021,37(4):257-264.TAO Y,XU J,REN H J,et al.Spatiotemporal evolution of agricultural non-point source pollution and its influencing factors in the Yellow River Basin[J].Transactions of the Chinese Society of Agricultural Engineering,2021,37(4):257-264.
基本信息:
DOI:10.13928/j.cnki.wrahe.2026.04.010
中图分类号:X52;X71
引用信息:
[1]侯晓辉,龚洋慧,崔康成,等.模拟降水条件下农田径流面源污染形成机制与协同防控策略研究[J].水利水电技术(中英文),2026,57(04):135-145.DOI:10.13928/j.cnki.wrahe.2026.04.010.
基金信息:
国家自然科学基金项目(42277394); 河南省重点研发与推广专项(科技攻关)(232102320104)
2026-01-30
2026-01-30
2026-01-30