Abstract
Dongting Lake is the second largest freshwater lake in China. It is suffering from significant eutrophication as a result of excessive nutrients inputs, among which nitrogen (N) is becoming a major contributor. The objective of this study is to document the occurrence and controls on N transport and transformation in riparian zones of Dongting Lake wetland. Field experiments were conducted in the cultivated Li River (LR) and uncultivated Yuan River (YR) regions of the wetlands from June to November, 2014. Groundwater depth, redox potential (Eh), pH, and temperature were measured in situ. Groundwater and surface water samples were collected to determine concentrations of nitrate nitrogen (NO3 −–N), nitrite nitrogen (NO2 −–N), and ammonia nitrogen (NH4 +–N). The results showed that NH4 +–N was the dominant N pollutant with maximum average value of 2.7760 mg L−1. All the groundwater samples were rated to Class V based on NH4 +–N content according to the groundwater quality standard, indicating the load of N in riparian zones had exceeded their capacity for assimilation and purification. Internal controls (including Eh and pH, temperature, and groundwater depth) and external controls (including surface water, land use, and rainfall) were analyzed in detail. The results suggested that Eh and pH were more significant in controlling N transport and transformation than temperature and groundwater depth; external controls influenced N fates through imposing an effect on internal controls. This study will provide important insights and a scientific basis for N pollution treatment and better protection of the Dongting Lake wetlands.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Addiscott TM, Whitmore AP, Powlson DS (1991) Farming, fertilizers and the nitrate problem. CAB International (CABI), Wallingford
Agehara S, Warncke DD (2005) Soil moisture and temperature effects on nitrogen release from organic nitrogen sources. Soil Sci Soc Am J 69:1844–1855
Almasri MN, Kaluarachchi JJ (2004) Assessment and management of long-term nitrate pollution of ground water in agriculture-dominated watersheds. J Hydrol 295:225–245
Anderson DM, Glibert PM, Burkholder JM (2002) Harmful algal blooms and eutrophication: nutrient sources, composition, and consequences. Estuaries 25:704–726
Antonopoulos VZ (1999) Comparison of different models to simulate soil temperature and moisture effects on nitrogen mineralization in the soil. J Plant Nutr Soil Sci 162:667–675
Bowden WB (1987) The biogeochemistry of nitrogen in freshwater wetlands. Biogeochemistry 4:313–348
Brookins DG (1988) Eh-pH diagrams for geochemistry. Springer, Berlin
Burow KR, Nolan BT, Rupert MG, Dubrovsky NM (2010) Nitrate in groundwater of the United States, 1991–2003. Environ Sci Technol 44:4988–4997
Burt TP, Matchett LS, Goulding KWT, Webster CP, Haycock NE (1999) Denitrification in riparian buffer zones: the role of floodplain hydrology. Hydrol Process 13:1451–1463
Burt TP, Pinay G, Matheson FE, Haycock NE, Butturini A et al (2002) Water table fluctuations in the riparian zone: comparative results from a pan-European experiment. J Hydrol 265:129–148
Cambardella CA, Moorman TB, Jaynes DB, Hatfield JL, Parkin TB, Simpkins WW, Karlen DL (1999) Water quality in Walnut Creek watershed: nitrate-nitrogen in soils, subsurface drainage water, and shallow groundwater. J Environ Qual 28:25–34
Cey EE, Rudolph DL, Aravena R et al (1999) Role of the riparian zone in controlling the distribution and fate of agricultural nitrogen near a small stream in southern Ontario. J Contam Hydrol 37:45–67
Cheong JY, Hamm SY, Lee JH et al (2012) Groundwater nitrate contamination and risk assessment in an agricultural area, South Korea. Environ Earth Sci 66:1127–1136
Chislock MF, Doster E, Zitomer RA, Wilson AE (2013) Eutrophication: causes, consequences, and controls in aquatic ecosystems. Nat Educ Knowl 4:10
Conley DJ, Paerl HW, Howarth RW et al (2009) Ecology controlling eutrophication: nitrogen and phosphorus. Science 323:1014–1015
Deng F, Wang XL, Li EH et al (2012) Dynamics of Lake Dongting wetland from 1993 to 2010. J Lake Sci 24:571–576 (in Chinese)
Gao Y, Yu G, Luo C, Zhou P (2012) Groundwater nitrogen pollution and assessment of its health risks: a case study of a typical village in rural–urban continuum, China. PLoS One 7:e33982. doi:10.1371/journal.pone.0033982
Green DM, Kauffman JB (1989) Nutrient cycling at the land-water interface: the importance of the riparian zone. In Practical approaches to riparian resource management: an education workshop. US Bureau of Land Management. Billings, MT pp. 61–68
Gu B, Ge Y, Chang SX et al (2013) Nitrate in groundwater of China: sources and driving forces. Global Environ Chang 23:1112–1121
Guntinas ME, Leirós MC, Trasar-Cepeda C, Gil-Sotres F (2012) Effects of moisture and temperature on net soil nitrogen mineralization: a laboratory study. Eur J Soil Biol 48:73–80
Guo JP, Wu PC, Xiong JA (2007) Study on the water pollution and the preventing and controlling measures of Dongting Lake. J Hunan Univ Arts Sci (Soc Sci Ed) 32:91–94 (in Chinese)
Hefting M, Clement JC, Dowrick D, Cosandey AC et al (2004) Water table elevation controls on soil nitrogen cycling in riparian wetlands along a European climatic gradient. Biogeochemistry 67:113–134
Huang DZ, Wan Q, Li LQ et al (2013) Changes of water quality and eutrophic state in recent 20 years of Dongting Lake. Res Environ Sci 26:27–33 (in Chinese)
Isensee AR, Sadeghi AM (1995) Long-term effect of thj. age and rainfall on herbicide leaching to shallow groundwater. Chemosphere 30:671–685
Jack Brookshire EN, Gerber S, Webster JR et al (2011) Direct effects of temperature on forest nitrogen cycling revealed through analysis of long-term watershed records. Global Chang Biol 17:297–308
Kemp MJ, Dodds WK (2001) Spatial and temporal patterns of nitrogen concentrations in pristine and agriculturally-influenced prairie streams. Biogeochemistry 53:125–141
Korom SF (1992) Natural denitrification in the saturated zone: a review. Water Resour Res 28:1657–1668
Li YZ, Liu F, Zhang CM (2011) Analysis of change trend of water environment and cause in the Dongting Lake wetland. Ecol Environ Sci 20:1295–1300 (in Chinese)
Li F, Huang JH, Zeng GM et al (2014a) Integrated source apportionment, screening risk assessment, and risk mapping of heavy metals in surface sediments: a case study of the Dongting Lake, middle China. Hum Ecol Risk Assess 20:1213–1230
Li Y, Chen Z, Lou H, Wang D, Deng H, Wang C (2014b) Denitrification controls in urban riparian soils: implications for reducing urban nonpoint source nitrogen pollution. Environ Sci Pollut Res 21:10174–10185
Liang XJ, Xiao CL, Sheng HX et al (2007) Analysis on the influence factors of the nitrogen pollution in shallow groundwater. J Jilin Univ 37:335–340, 345 (in Chinese)
Liang J, Liu JY, Yuan XZ et al (2015) Spatial and temporal variation of heavy metal risk and source in sediments of Dongting Lake wetland, mid-south China. J Environ Sci Health 50:100–108
Liu GD, Wu WL, Zhang J (2005) Regional differentiation of non-point source pollution of agriculture-derived nitrate nitrogen in groundwater in northern China. Agric Ecosyst Environ 107:211–220
Liu X, Vidon P, Jacinthe PA, Fisher K, Baker M (2014) Seasonal and geomorphic controls on N and P removal in riparian zones of the US Midwest. Biogeochemistry 119:245–257
Lowrance R, Todd R, Fail J, Hendrickson O, Leonard R, Asmussen L (1984) Riparian forests as nutrient filters in agricultural watersheds. Bioscience 34:374–377
Masscheleyn PH, Delaune RD, Patrick WH Jr (1991) Effect of redox potential and pH on arsenic speciation and solubility in a contaminated soil. Environ Sci Technol 25:1414–1419
McKinstry MC, Hubert WA, Anderson SH (2004) Wetland and riparian areas of the intermountain west: ecology and management (no. 4). University of Texas Press, Austin
McNeal BL, Pratt PF (1978) Leaching of nitrate from soils. In: Pratt PF (ed) Proceedings of national conference on management of nitrogen in irrigated agriculture. University of California, Riverside, pp 195–230
Mitsch WJ, Gosselink James G (2008) Wetlands. Van Nostrand Reinhold Company Inc, New York
Rabalais NN (2002) Nitrogen in aquatic ecosystems. Ambio 31:102–112
Reddy KR, DeLaune RD (2004) Biogeochemistry of wetlands: science and applications. Crc Press, Boca Raton
Rivett MO, Buss SR, Morgan P et al (2008) Nitrate attenuation in groundwater: a review of biogeochemical controlling processes. Water Res 42:4215–4232
Robertson WD, Russell BM, Cherry JA (1996) Attenuation of nitrate in aquitard sediments of southern Ontario. J Hydrol 180:267–281
Sanchez-Pérez JM, Vervier P, Garabétian F et al (2003) Nitrogen dynamics in the shallow groundwater of a riparian wetland zone of the Garonne, SW France: nitrate inputs, bacterial densities, organic matter supply and denitrification measurements. Hydrol Earth Sys Sci Discuss 7:97–107
Shen RL, Zhang JX, Bao ZY et al (2006) Water quality assessment in Lake Dongting (2002–2004), China. Sci Limnol Sin 18:243–249 (in Chinese)
Sims JT (1986) Nitrogen transformations in a poultry manure amended soil: temperature and moisture effects. J Environ Qual 15:59–63
Smil V (2004) Enriching the earth: fritz haber, carl bosch, and the transformation of world food production. MIT Press, Cambridge
Smith VH, Tilman GD, Nekola JC (1999) Eutrophication: impacts of excess nutrient inputs on freshwater, marine, and terrestrial ecosystems. Environ Pollut 100:179–196
State Environmental Protection Administration of China (1994) Chinese groundwater quality criteria of classification (GB/T14848-93). China Environmental Science Press, Beijing, pp 23–32, in Chinese
Strous M, Fuerst JA, Kramer EHM et al (1999) Missing lithotroph identified as new planctomycete. Nature 400:446–449
Stuart ME, Gooddy DC, Bloomfield JP, Williams AT (2011) A review of the impact of climate change on future nitrate concentrations in groundwater of the UK. Sci Total Environ 409:2859–2873
Swanson FJ, Gregory SV, Sedell JR, Campbell AG (1982) Land-water interactions: the riparian zone. In: Edmonds RL (ed) Analysis of coniferous forest ecosystems in the western United States. Hutchinson Ross, Pennsylvania, pp 267–291
Takatert N, Sanchez‐Pérez JM, Trémoliéres M (1999) Spatial and temporal variations of nutrient concentration in the groundwater of a floodplain: effect of hydrology, vegetation and substrate. Hydrol Process 13:1511–1526
Tu JW (2001) Hydrogeological present situation of regional environment in Dongtinghu district. Hunan Geol 20:203–206 (in Chinese)
Vidon PG, Hill AR (2004) Landscape controls on nitrate removal in stream riparian zones. Water Resour Res 40:W03201. doi:10.1029/2003WR002473
Wang LQ, Liang T, Zhong BQ et al (2014) Study on nitrogen dynamics at the sediment–water interface of Dongting Lake, China. Aquat Geochem 20:501–517
Winter Thomas C (1999) Relation of streams, lakes, and wetlands to groundwater flow systems. Hydrogeol J 7:28–45
Yang ZF, Yu T, Tang JR et al (2006) A study of the characteristics and mechanisms of soil acidification in the Dongting Lake region in Hunan Province, South China. Earth Sci Front 13:105–112 (in Chinese)
Yang Y, Wang X, Shi J et al (2012) The influence of the discharging sewage on microbial diversity in sludge from Dongting Lake. World J Microbiol Biotechnol 28:421–430
Acknowledgments
The author thanks the anonymous reviewers for their comments on this manuscript. This study is supported by the National Science Fund of China (No. 41272249), Research Fund for the Doctoral Program of Higher Education of China (No. 20110072110020).
Author information
Authors and Affiliations
Corresponding author
Ethics declarations
Funding
This study was funded by National Science Fund of China (No. 41272249), Research Fund for the Doctoral Program of Higher Education of China (No.20110072110020).
Conflict of interest
The authors declare that they have no competing interests.
Additional information
Responsible editor: Hailong Wang
Rights and permissions
About this article
Cite this article
Zhao, S., Zhou, N. & Liu, X. Occurrence and controls on transport and transformation of nitrogen in riparian zones of Dongting Lake, China. Environ Sci Pollut Res 23, 6483–6496 (2016). https://doi.org/10.1007/s11356-015-5865-9
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11356-015-5865-9