Migration of Infiltrated NH_4 and NO_3 in a Soil and Groundwater System Simulated by a Soil Tank 被引量：1

Migration of Infiltrated NH_4 and NO_3 in a Soil and Groundwater System Simulated by a Soil Tank

下载PDF

导出

摘要 The infiltration of water contaminants into soil and groundwater systems can greatly affect the quality of groundwater. A laboratory-designed large soil tank with periodic and continuous infiltration models, respectively, was used to simulate the migration of the contaminants NH4 and NO3 in a soil and groundwater system, including unsaturated and saturated zones. The unsaturated soil zone had a significant effect on removing NH4 and NO3 infiltrated from the surface water. The patterns of breakthrough curves of NH4 and NO3 in the unsaturated zone were related to the infiltration time. A short infiltration time resulted in a single sharp peak in the breakthrough curve, while a long infiltration time led to a plateau curve. When NH4 and NO3 migrated from the unsaturated zone to the saturated zone, an interracial retardation was formed, resulting in an increased contaminant concentration on the interface. Under the influence of horizontal groundwater movement, the infiltrated contaminants formed a contamination-prone area downstream. As the contaminants migrated downstream, their concentrations were significantly reduced. Under the same infiltration concentration, the concentration of NO3 was greater than that of NH4 at every corresponding cross-section in the soil and groundwater tank, suggesting that the removal efficiency of NH4 was greater than that of NO3 in the soil and groundwater system. The infiltration of water contaminants into soil and groundwater systems can greatly affect the quality of groundwater. A laboratory-designed large soil tank with periodic and continuous infiltration models,respectively,was used to simulate the migration of the contaminants NH4 and NO3 in a soil and groundwater system,including unsaturated and saturated zones. The unsaturated soil zone had a significant effect on removing NH4 and NO3 infiltrated from the surface water. The patterns of breakthrough curves of NH4 and NO3 in the unsaturated zone were related to the infiltration time. A short infiltration time resulted in a single sharp peak in the breakthrough curve,while a long infiltration time led to a plateau curve. When NH4 and NO3 migrated from the unsaturated zone to the saturated zone,an interfacial retardation was formed,resulting in an increased contaminant concentration on the interface. Under the infiuence of horizontal groundwater movement,the infiltrated contaminants formed a contamination-prone area downstream. As the contaminants migrated downstream,their concentrations were significantly reduced. Under the same infiltration concentration,the concentration of NO3 was greater than that of NH4 at every corresponding cross-section in the soil and groundwater tank,suggesting that the removal effciency of NH4 was greater than that of NO3 in the soil and groundwater system.

作者 WANG Chao WANG Pei-Fang

机构地区 State Key Laboratory of Hydrology- Water Resources and Hydraulic Engineering

出处《Pedosphere》 SCIE CAS CSCD 2008年第5期628-637,共10页 土壤圈（英文版）

基金 the National Key Basic Research Program (973 Program) of China (No.2002CB412303) the National Natural Science Foundation of China (No.50709009) the Key Project of Chinese Ministry of Education (No.106088).

关键词 breakthrough curve MIGRATION NH4 NO3 soil tank experiment 土壤实验研究氨三氧化氮地下迁移

分类号 S15 [农业科学—土壤学]

引文网络
相关文献

参考文献34

1Behera, S., Jha, M. K. and Kar, S. 2003. Dynamics of water flow and fertilizer solute leaching in lateritic soils of Kharagpur region, India. Agr. Water Manage. 63:77-98.
2Bouwer, H. 1987. Effect of irrigated agriculture on groundwater. J. Irrig. Drain. Eng. 113(1): 4-15.
3Costa, J. L., Massone, H., Martinez, D., Suero, E. E., Vidal, C. M. and Bedmar, F. 2002. Nitrate contamination of a rural aquifer and accumulation in the unsaturated zone. Agr. Water Manage. 57:33-47.
4de Rooij, G. H. and Stagnitti, F. 2000. Spatial variability of solute leaching: Experimental validation of a quantitative parameterization. Soil Sci. Soc. Am. J. 64(2): 499-504.
5De Smedt, F. and Wierenga, P. J. 1984. Solute transfer through columns of glass beads. Water Resour. Res. 20(2): 225-232.
6Ersahin, S. 2001. Assessment of spatial variability in nitrate leaching to reduce nitrogen fertilizers impact on water quality. Agr. Water Manage. 48: 179-189.
7Feng, Z. Z., Wang, X. K. and Feng, Z. W. 2005. Soil N and salinity leaching after the autumn irrigation and its impact on groundwater in Hetao Irrigation District, China. Agr. Water Manage. 71: 131-143.
8Hancock, C. M., Rose, J. B., Vasconcelos, G. J., Harris, S. I., Klonicki, P. T. and Sturbaum, G. D. 2000. Giardia and Cryptosporidium occurrence in groundwater. J. Am. Water Works Assoc. 92(9): 117-123.
9Haruvy, N., Hadas, A. and Hadas, A. 1997. Cost assessment of various means of averting environmental damage and groundwater contamination from nitrate seepage. Agr. Water Manage. 32(3): 307-320.
10Hideo, N., Muhammad, A. A. and Hisao, K. 2004. Nitrogen transport and transformation in packed soil columns from paddy fields. Paddy Water Environ. 2: 115-124.

同被引文献15

1梁运江,依艳丽,许广波,张爽,尹英敏.水肥耦合效应对保护地土壤硝态氮运移的影响[J].农村生态环境,2004,20(3):32-36. 被引量：20
2杜春先,聂俊华,王介勇.不同水肥条件下硝态氮在土壤剖面中垂直分布规律研究[J].土壤通报,2006,37(2):278-281. 被引量：22
3马雪姣,王学东,王殿武,许嗥,黄元仿.不同水氮供应对菜地土壤硝态氮累积的影响[J].南水北调与水利科技,2006,4(4):29-32. 被引量：1
4刘洋,张玉龙,杨丽娟,王耀生,赵昕欣.渗灌管埋深对土壤硝态氮含量的影响[J].节水灌溉,2006(5):15-17. 被引量：9
5杨治平,陈明昌,张强,张建杰.不同施氮措施对保护地黄瓜养分利用效率及土壤氮素淋失影响[J].水土保持学报,2007,21(2):57-60. 被引量：42
6王立河,赵喜茹,王喜枝,谭金芳,王立秋,孙新政.有机肥与氮肥配施对日光温室黄瓜和土壤硝酸盐含量的影响[J].土壤通报,2007,38(3):472-476. 被引量：51
7周茂娟,梁银丽,陈甲瑞,熊亚梅,韦泽秀.地表处理方式对日光温室辣椒水分利用效率及土壤硝态氮、速效磷分布的影响[J].应用生态学报,2007,18(6):1393-1396. 被引量：13
8袁巧霞,武雅娟,艾平,甄玉存,朱端卫.温室土壤硝态氮积累的温度、水分、施氮量耦合效应[J].农业工程学报,2007,23(10):192-198. 被引量：19
9Oelmanna Y,Kreutzigerc Y,Bold R. et al.Nitrate leaching in soil:Tracing the NO3-sources with the help of stable N and O. Soil Biology and Biochemistry . 2007
10姬景红,张玉龙,黄毅,虞娜,张玉玲.灌溉方法对保护地土壤有机氮组分及剖面分布的影响[J].水土保持学报,2007,21(6):99-104. 被引量：27

引证文献1

1袁静超,张玉龙,虞娜,陈璟丽,王芳,肖质秋.水肥耦合条件下保护地土壤硝态氮动态变化[J].土壤通报,2011,42(6):1335-1340. 被引量：5

二级引证文献5

1程文娟,潘洁,吕雄杰,赵先胜,Christoph Poschenrieder,胡云才,Urs Schmidhalter.天津市设施蔬菜土壤硝态氮状况研究[J].天津农业科学,2012,18(2):91-94. 被引量：5
2岳文俊,张富仓,李志军,邹海洋,高月.水氮耦合对甜瓜氮素吸收与土壤硝态氮累积的影响[J].农业机械学报,2015,46(2):88-96. 被引量：52
3司转运,高阳,申孝军,刘浩,龚雪文,段爱旺.水氮供应对夏棉产量、水氮利用及土壤硝态氮累积的影响[J].应用生态学报,2017,28(12):3945-3954. 被引量：21
4赵经华,杨庭瑞,胡文军,阿依古丽·吾守尔,艾麦提·艾麦尔,陈凯丽.水氮互作对滴灌小麦土壤硝态氮运移、氮平衡及水氮利用效率的影响[J].中国农村水利水电,2021(4):141-149. 被引量：20
5张绍武,胡田田,刘杰,冯璞玉,张美玲.滴灌施肥下水肥用量对温室土壤硝态氮残留的影响[J].灌溉排水学报,2019,38(3):56-63. 被引量：7

1李贵桐,李保国,黄元仿.碳源与底物对不同层次土壤产生N_2O能力的影响[J].土壤与环境,2002,11(3):227-231. 被引量：7
2ZHANG Ming-Kui.Effects of Soil Properties on Phosphorus Subsurface Migration in Sandy Soils[J].Pedosphere,2008,18(5):599-610. 被引量：14
3Huanxin WENG Ailan YAN Xiuhui SONG Chunlai HONG.Migration and bio-absorption of ^(125)I in soil[J].Chinese Journal Of Geochemistry,2006,25(B08):77-77.
4FANG Fu-ping,FENG Jin-fei,LI Feng-bo,PENG Shao-bing.Impacts of the north migration of China＇s rice production on its ecosystem service value during the last three decades (1980-2014)[J].Journal of Integrative Agriculture,2017,16(1):76-84. 被引量：2
5PEICHUM CHANG KYOUNG- WOONG KIM SATOSHI YOSHIDA 赵玉军（译）.柠檬酸增强铀在林木植物中的堆积[J].水文地质工程地质技术方法动态,2005(6):27-33. 被引量：1
6Andrew Willden.New Genetic Evidence Supports Initial Migration of Settlers into Eastern Asia via Myanmar[J].Bulletin of the Chinese Academy of Sciences,2015,29(2):109-110.
7Qu Cuihui,Wang Wuyi(Institute of Geography, CAS, Beijing 100101People’s Republic of China).FACTORS CONTROLLING DIFFERENTIATION OF SELENIUM ECONVIRONMENT IN THE LOESS PLATEAU[J].Journal of Geographical Sciences,1994,4(Z1):138-145.
8SONG Hai-xing,LI Sheng-xiu.Root Function in Nutrient Uptake and Soil Water Effect on NO3^- -N and NH4^+ -N Migration[J].Agricultural Sciences in China,2006,5(5):377-383. 被引量：2
9TANG Jian ,CNRRI,Hangzhou 310006,China.Long range migration of rice planthoppers and associated meteorological conditions in Yulin,Ganzhou,and Huangyan[J].Chinese Rice Research Newsletter,1995,3(1):8-10.
10Natalia Kuzmenkova,Alexei Miroshnikov.Distribution of ^(137)Cs in Tundra Soils(Kola Peninsula)[J].地学前缘,2009,16(S1):235-235.

Pedosphere

2008年第5期

浏览历史

内容加载中请稍等...

Migration of Infiltrated NH_4 and NO_3 in a Soil and Groundwater System Simulated by a Soil Tank 被引量：1

参考文献34

同被引文献15

引证文献1

二级引证文献5

相关作者

相关机构

相关主题

浏览历史