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Biogeochemistry

, Volume 57, Issue 1, pp 387–403 | Cite as

Nitrogen budgets for the Republic of Korea and the Yellow Sea region

  • V.N. Bashkin
  • S.U. Park
  • M.S. Choi
  • C.B. Lee
Article

Abstract

Growing populations in northeast Asia have greatly altered the nitrogencycle, with increases in agricultural production to feed the population, andwith increases in N emissions and transboundary air pollution. For example,during the 1900's over 50% of the N deposition over Republic of Korea wasimported from abroad. In this paper, we present biogeochemical budgets ofN for the South Korean peninsula (the Republic of Korea) and for the YellowSea region. We quantify N inputs from atmospheric deposition, fertilizers,biological fixation, and imports of food, feed, and products. We quantifyoutputs in riverine export, crop uptake, denitrification, volatilization,runoff, sedimentation and sea water exchange. Calculations were conductedusing mean values from 1994–1997. All of the nitrogen budgets werepositive, with N inputs exceeding outputs. The excess N inputs gave rise toincreases in N storage in landfills and in groundwater. Annual accumulationof N in the Yellow sea, including inputs from South Korea and otherdrainage areas, was 1229 kt yr−1 with a residence time for N ofapproximately 1.5 years, thus doubling N content in marine waters every 3years during 1994–1997. The human derived N inputs leads to excessiveeutrophication and pollution of the Yellow Sea.

anthropogenic loading biogeochemical cycling Korea nitrogen deposition Northeast Asia regional budget 

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References

  1. Bashkin VN (1984) Study of landscape-agrogeochemical balance of nutrients in agricultural regions, II: Potassium. Water, Air and Pollution 21: 97–103Google Scholar
  2. Bashkin VN, Erdman LK, Abramychev AY, Sofiev MA, Priputina IV & Gusev A (1997) The input of anthropogenic airborne nitrogen to the Mediterranean Sea through its watershed. MAP Technical Reports Series No. 118, UNEP, Athens, 95 ppGoogle Scholar
  3. Bashkin V & Park SU (Eds) (1998) Acid deposition and ecosystem sensitivity in East Asia, NovaScience Publisher, 427 ppGoogle Scholar
  4. Carmichael GR, Hong MS, Ueda H, Chen LL, Murano K, Park JK, Lee H, Kim Y, Kang C & Shim S (1997) Aerosol composition at Cheju Island, Korea. Journal of Geophysics Research 102: 6047–6061Google Scholar
  5. Cha HJ, KimJY, Koh CH & Lee CB (1998) Temporal and spatial variation of nutrient elements in surface seawater of the west coast of Korea. The Journal of the Korean Society of Oceanography 3: 25–33Google Scholar
  6. Choi MS (1998) Distribution of trace metals in the riverine, atmospheric and marine environments of the western coast of Korea. PhD thesis, Department of Oceanography, Seoul National University, 338 ppGoogle Scholar
  7. Cleveland CC, Townsend AR, Schimel DS, Fisher H, Howarth RW, Hedin LO, Perakis SS, Latty EF, von Fischer JC, Eleseroad A & Wasson MF (1999) Global patterns of terrestrial biological nitrogen fixation in natural ecosystems. Global Biogeochemical Cycles 13: 623–646Google Scholar
  8. Dentener FJ & Crutzen PJ (1994) A three dimensional model of the global ammonia cycle. Journal of Atmospheric Chemistry 19: 331–369Google Scholar
  9. Environmental Statistics Yearbook (1998) Ministry of Environment, Republic of Korea, 581 ppGoogle Scholar
  10. Erisman JW, Brydges T, Bull K, Cowling E, Grennfelt P, Nordberg L, Satake K, Scheider T, Smeulders S, van der Hoek K, Wisniewski J & Wisniewski J (1999) Summary statement. In: International Nitrogen conference, Elsevier ScienceGoogle Scholar
  11. ESCAP (1998) Sources and Nature of Water Quality Problems in Asia and the Pacific, New York, United Nations, 164 ppGoogle Scholar
  12. ESCAP (1997) Sustainable Development of Water Resources in Asia and the Pacific: an overview, New York, United Nations, 162 ppGoogle Scholar
  13. Gao Y, Arimoto R, Duce A, Lee DS & Zhou MY (1992) Input of atmospheric trace elements and mineral matter to the Yellow Sea during the spring of a low-dust year. Journal of Geophysics Research 97: 3767–3777Google Scholar
  14. Gundersen P & Gashkin VN (1994) Nitrogen cycling. In: Moldan & Cherny J (Eds) Biogeochemistry of Small Catchments. John Wiley and Sons, pp 253–277Google Scholar
  15. Freney JR (1996) Control of nitrogen emission from agriculture. In: Lin HC et al. (Eds) Proceedings of SCOPE/ICSU Nitrogen Workshop: The Effect of Human Disturbance on the Nitrogen Cycle in Asia, pp 85–99Google Scholar
  16. Howarth RW (Ed) (1996) Nitrogen Cycling in the North Atlantic Ocean and its Watersheds. Kluwer Academic Publishers, 304 ppGoogle Scholar
  17. IPCC (1997) Guidelines for National Greenhouse Gas Inventories. OECD/ICDE, ParisGoogle Scholar
  18. Iserman K (1991) Share of agriculture in nitrogen and phosphorus emission into the surface waters of Western European against the background of their eutrophication. Fertilizer Research 26: 253–269Google Scholar
  19. Lewis WM, Melack JM, McDowell WH, McClain ME & Richey JE (1999) Nitrogen yields from undisturbed watershed in the Americas. Biogeochemistry 46: 149–162Google Scholar
  20. Lin H-C, Yang S-S, Hung T-C & Chou C-H (Eds) (1996) The Effect of Human Disturbance on the Nitrogen Cycle in Asia, Proceedings of SCOPE/ICSU Nitrogen WorkshopsGoogle Scholar
  21. Moldan B & Cherny J (Eds) (1994) Biogeochemistry of Small Catchments. John Wiley and Sons, 424 ppGoogle Scholar
  22. Mosier A, Abrahamsen G, Bouwman L, Bockman O, Drange H, Forlking S, Howarth R, Kroeze C, Oenema O, Smith K & Bleken M (Eds) (1998) International workshop on dissipation of N from the human N cycle and its role in present and future N2O emissions to the atmosphere. Nutrient Cycling in Agroecosystems. Kluwer Academic Publishers, 313 ppGoogle Scholar
  23. Nixon SW, Ammerman JW, Atkinson LP, Berounsky VM, Billen G, Boicourt WC, Boynton WR, Church TM, Ditoro DM, Elmgren R, Garber JM, Giblin AE, Jahnke RA, Owens NJP, Pilson JH & Seitzinger SP (1996) The fate of nitrogen and phosphorus at the landsea margin of the North Atlantic Ocean. In: Howarth RW (Ed) Nitrogen Cycling in the North Atlantic Ocean and its Watersheds. Kluwer Academic Publishers, pp 141–180Google Scholar
  24. Park SU (Ed) (1998) Research and Development on Basic Technology for Atmospheric Environment in Global Scale: Development of Technology for Monitoring and Prediction of Acid Rain. Ministry of Environment, Republic of Korea, 602 ppGoogle Scholar
  25. Seung YH & Park YC (1990) Physical and environmental character of the Yellow Sea. In: Park CH, Kim DH & Lee SH (Eds) The Regime of the Yellow Sea. Institute of East and West Staudies, Seoul, pp 9–38Google Scholar
  26. Sofiev MA (1998) Numerical modeling for Acid deposition on Eurasian continent. In: Bashkin VN & Park SU (Eds) Acid Deposition and Ecosystem Sensitivity in East Asia. Nova Science Publishers, U.S.A., pp 5–48Google Scholar
  27. Um KT (1985) Soils of Korea. Soil Survey Materials No. 11. Agricultural Science Institute, Rural Administration, Korea, 66 ppGoogle Scholar
  28. UNESCO (1978) World Water Balance and Water Resources of the Earth. Gidrometeoizdat Publishers, Leningrad, 666 ppGoogle Scholar
  29. Zhang J, Huang WW, Liu SM & Wang JH (1992) Transport of particulate heavy metals towards the China Sea: a preliminary study and comparison. Marine Chemistry 40: 161–178Google Scholar
  30. Zhu ZL (Ed) (1997) Nitrogen Balance and Cycling in Agroecosystems of China. Kluwer Academic Publisher, 355 ppGoogle Scholar
  31. Zimmermann PH (1998) Moguntia: A handy global tracer model. In: van Dop H (Ed) Air Pollution Modeling and its Applications VI. Plenum, New YorkGoogle Scholar
  32. Xing GX & Zhu ZL (2002) Regional nitrogen budgets for China and its major watersheds. Biogeochemistry 57/58: 405–427Google Scholar

Copyright information

© Kluwer Academic Publishers 2002

Authors and Affiliations

  1. 1.Department of Atmospheric SciencesSeoul National University, SeoulRepublic of Korea;
  2. 2.School of Energy and Materials, KMUTTJGSEETungkru BangkokThailand
  3. 3.Department of OceanographySeoul National UniversitySeoulRepublic of Korea

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