Korean Journal of Ecology and Environment (생태와환경)

The Korean Society of Limnology (한국수생태학회)
권호 표지

Comparison of the Fertility of Stream Waters Depending on the Drainage Systems in the Lake Shihwa Watershed, Korea

시화호 유역에서 배수시스템별 하천수의 비옥도 비교

  • Shin, Jae-Ki (Department of Biological Systems Engineering, Konkuk University) ;
  • Kim, Dong-Sup (Water Resources Research Institute, Korea Water Resources Corporation (KOWACO)) ;
  • Kang, Chang-Keun (Division of Environment Management, National Fisheries Research & Development Institute (NFRDI)) ;
  • Hwang, Soon-Jin (Development Institute (NFRDI))
  • 신재기 (건국대학교 지역건설환경공학과) ;
  • 김동섭 (한국수자원공사 수자원연구원) ;
  • 강창근 (국립수산과학원 환경관리과) ;
  • 황순진 (건국대학교 지역건설환경공학과)
  • Published : 2003.09.30
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Abstract

The fertility of stream water in major streams of the Lake Shihwa Watershed was compared using water analyses and algal growth potential test (AGPT) in typical drought seasons from December 2001 to April 2002, The water quality varied considerably depending on streams. These streams were very rich in inorganic nutrients that the nutrient levels and characteristics of each stream could be easily determined. Through AGPT, 63.6% of growth was observed in the average values of each stream, with non-growth accounting for 36.4%. AGPT results showed that 40.9% of the 22 stations were in hypertrophic condition and 54.5% in eutrophic condition. AGPT values were significantly correlated with TIN, $NH_4$, and SRP (p <0.001); compared to other nutrients, however, they were more related to SRP and $NH_4$. Moreover, the values increased with high concentration of N and P and low N/P ratios. Nonetheless, the values were more dependent on P concentration than N concentration. This suggests that the effect of P on the water quality of lake situated in downstream may serve as a potential indicator of phytoplankton development. Depending on the drainage pattern of streams, the wastewaters of wastewater treatment plant (WwTP) and untreated wastewater (UTW) were found to have 53.4% and 46.6%, respevtively, of TIN, 51.9% and 48.1% of $NH_4$, 62.9% and 37.1% of $NO_3$, 62.6% and 37.4% of SRP, and 44.1% and 55.9% of SRSi. The AGPT value was 51.1% in WwTP wastewater and 48.9% in UTW wastewater, the concentration of WwTP wastewater was slightly higher. For untreated wastewaters flowing into the constructed wetland and into the lake, TIN accounts for 43.0% and 57.0%, respectively, of nitrogen components, $NH_4$ 44.4% and 55.6%, $NO_3$ 39.6% and 60.4%, SRP 53.5% and 46.5%, and SRSi 52.3% and 47.7%, respectively. The AGPT value was 58.0% in the constructed wetland and 42.0% in Lake Shihwa; the concentration in streams flowing into the wetland was slightly higher. Therefore, Persistent and large development of phytoplankton in Lake Shihwa cannot be prevented unless a measure tophytoplankton control is implemented. This is because the concentration of nutrients in specific streams flowing into the lake is very high, even though the inflow of water is low.

Keywords

References

  1. 기상청. 2001. http://www.kma.go.kr, 기후자료: 1991-2000인천, 수원 강수량.
  2. 신재기, 김동섭, 조경제. 2000a. 시화호에서 무기영양염과 식물플랑크톤의 동태. 한국육수학회지 33: 109-118.
  3. 신재기, 김동섭, 조경제. 2000b. 시화호에서 해수유입 전∙후의 수환경 요인과 식물플랑크톤의 동태. 한국환경과학회지 9: 115-123.
  4. 신재기, 이옥희, 황순진, 조경제. 2001. 경안천에서 하수처리수와 생하수에 대한 algal bioassay. 한국육수학회지 34:192-198.
  5. 신재기, 조경제. 2000. 금강 중∙하류에서 AGP에 의한 수질평가. 한국육수학회지 33: 244-250.
  6. 신재기. 1998. 낙동강 부영양화에 따른 담수조류의 생태학적연구. 인제대학교 박사학위논문. 202pp.
  7. APHA, AWWA, WEF. 1995. Standard Methods for theExamination of Water and Wastewater, 18th ed.American Public Health Association, Washington, DC.
  8. Claesson, A. and A. Forsberg. 1978. Algal assay procedurewith one or five species. Minitest. Mitt. Internat. Verein.Limnol. 21: 21-30.
  9. Miller, W.E., T.E. Maloney and J.C. Greene. 1974. Algalproductivity in 49 lake waters as determined by algalassays. Wat. Res. 8: 667-679.
  10. OECD. 1982. Eutrophication of Waters: Monitoring, Assessmentand Control. Organisation for Economic Cooperationand Development, Paris, France. 154pp.
  11. Porcella, D.B. and A.B. Bishop. 1975. Comprehensive managementof phosphorus water pollution. Ann. Arbor.Science, Ann. Arbor, Mich. 303pp.
  12. SPSS. 1998. SYSTAT® 8.0 statistics. SPSS Inc., Chicago,USA. 1086pp.
  13. Strickland, J.D. and T.R. Parsons. 1972. A Practical Handbookof Seawater Analysis. Bulletin of Fisheries ResearchBoard of Canada. No. 167. 310pp.
  14. Sudo, R. 1980. Studies on the water-blooms in lake Kasumigaura.Jpn. J. Limnol. 41: 124-131.
  15. Thornton, K.W., B.L. Kimmel and F.E. Payne. 1990. Reservoirlimnology: Ecological perspectives. John Wiley &Sons, Inc., New York, USA. 246pp.
  16. UN (United Nations). 1992. Protection of inland watersagainst eutrophication. New York, ECE/ENVWA/26.29pp.
  17. Watanabe, M. 1996. Isolation, cultivation and classificationof bloom-forming Microcystis in Japan. In, Watanabe,M.F., K. Harada, W.W. Carmichael and H. Fujiki. (eds).Toxic Microcystis. pp. 13-34. CRC Press, Boca Raton,London.
  18. Wetzel, R.G. 2001. Limnology: Lake and River Ecosystems.3rd Edition. Academic Press, California, USA. 1006pp.