Ocean and Polar Research

  • 제30권4호
  • /
  • Pages.379-399
  • /
  • 2008
  • /
  • 1598-141X(pISSN)
  • /
  • 2234-7313(eISSN)
한국해양과학기술원 (Korea Institute of Ocean Science & Technology)
권호 표지
DOI QR코드

DOI QR Code

한국 서해 중부 연안역의 수질환경 특성

Water Quality Characteristics Along Mid-western Coastal Area of Korea

  • 임동일 (한국해양연구원 남해특성연구부) ;
  • 강미란 (한국해양연구원 남해특성연구부) ;
  • 장풍국 (한국해양연구원 남해특성연구부) ;
  • 김소영 (한국해양연구원 남해특성연구부) ;
  • 정회수 (한국해양연구원 연구개발실) ;
  • 강양순 (국립수산과학원 해양환경연구본부) ;
  • 강영실 (국립수산과학원 해양환경연구본부)
  • 발행 : 2008.12.30
PDF 다운로드
⟨ 이전 논문 다음 논문 ⟩

초록

Spatial-temporal variations in physiochemical water qualities (temperature, salinity, DO, SPM, POC and nutrients) of surface and bottom waters were investigated along the mid-western coastal area (Taean Peninsula to Gomso Bay) of Korea. Spatial distribution patterns of temperature and salinity were mostly controlled by the physical mixing process of freshwater from Geum River and/or Gyunggi Bay with nearby coastal water. A strong tidal front is formed off Taean Peninsula during spring and summer. Seasonal variations in nutrient concentrations, lower in spring and summer and higher in fall and winter, are primarily regulated by magnitude of phytoplankton occurrence rather than freshwater loadings into the bay. Based on seasonal and spatial variability of physicochemical parameters, water quality of the study area can be divided into four water masses; Gyunggi Bay-influenced Water Mass (GBWM), Geum River-influenced Water Mass (GRWM), Yellow Sea Bottom Cold Water Mass (YSBCWM) and Cheonsu Bay Water Mass (CBWM). Water quality of the GBWM (Taean Peninsula coastal area), which has relatively low salinity and high concentrations of nutrients, is strongly controlled by the Gyunggi Bay coastal water, which is under influence of the Han River freshwater. In this water mass, the mixed layer is always developed by strong tidal mixing. As a result, a tidal front is formed along the offshore boundary of the mixed layer. Such tidal fronts probably play an important role in the distribution of phytoplankton communities, SPM and nutrients. The GRWM, with low salinity and high nutrients, especially during the flood summer season, is closely related to physiochemical properties of the Geum River. During the flood season, nutrient-enriched Geum River water mass extends up to 60 km away from the river mouth, potentially causing serious environmental problems such as eutrophication and unusual and/or noxious algal blooms. Offshore (<$30{\sim}40m$ in water depth) of the study area, YSBCWM coupled with a strong thermocline can be identified in spring-summer periods, exhibiting abundant nutrients in association with low temperature and limited biological activity. During spring and summer, a tidal front is formed in a transition zone between the coastal water mass and bottom cold water mass in the Yellow Sea, resulting in intensified upwelling and thereby supplying abundant nutrients to the GBWM and GRWM. Such cold bottom water mass and tidal front formation seems to play an important role in controlling water quality and further regulating physical ecosystem processes along mid-western Korean coastal area.

키워드

참고문헌

  1. 권기영, 문창호, 양한섭. 2001a. 섬진강 하구역에서 염분경사에 따른 영양염의 거동. 한국수산학회지, 34, 199-206
  2. 권기영, 이평강, 박철, 문창호, 박미옥. 2001b. 섬진강 하구역에서 염분경사에 따른 동-식물플랑크톤의 현종량 및 종조성. 한국해양학회지 바다, 6, 93-102
  3. 기상청. 2006. 기상월보 2006
  4. 김동선, 임동일, 전수경, 정회수. 2005. 한국 서해 천수만의 화학적 수질특성과 부영양화. Ocean and Polar Res., 27, 45-58 https://doi.org/10.4217/OPR.2005.27.1.045
  5. 김학균. 1989. 마산만의 편모조 적조의 발생과 환경특성. 국립수산진흥원 연구보고서, 43, 1-40
  6. 박승윤, 박경수, 김형철, 김평중, 김전풍, 박중현, 김숙양. 2006. 천수만의 수질환경 특성과 장기변동. 한국환경과학회지, 15, 447-459 https://doi.org/10.5322/JES.2006.15.5.447
  7. 신은주, 이상호, 최현용. 2002. 금강 풀룸의 구조와 분포에 대한 수치모델 연구. 한국해양학회지 바다, 7, 157-170
  8. 양재삼, 최현용, 정해진, 정주영, 박종규. 2000. 전남 고흥 해역의 유해성 적조의 발생연구: 1. 물리-화학적인 특성. 한국해양학회지 바다, 5, 16-26
  9. 이동섭. 1999. 여름과 겨울철 남해의 영양염 분포 특성. 한국해양학회지, 4, 371-382
  10. 이상호, 권효근, 최현용, 양재삼, 최진용. 1999. 하구언 수문작동으로 인한 금강 하구역의 물리적 환경변화 II. 염분구조와 하구유형. 한국해양학회지 바다, 4, 255-165
  11. 이상호, 최현용, 손영태, 권효근, 김영곤, 양재삼, 정해진, 김종구. 2003. 하계 서해안 새만금 연안역 주변 저염수와순환. 한국해양학회지 바다, 8, 138-150
  12. 임동일, 엄인권, 전수경, 유재명, 정회수. 2003. 한국 남해 연안역에서 여름 홍수기에 형성된 연안 염하구 환경의 물리-화학적 특성. 한국해양학회지 바다, 8, 151-163
  13. 임동일, 노경찬, 장풍국, 강선미, 정회수, 정래홍, 이원찬. 2007a. 한국 서해 경기만 연안역에서 수질환경의 시 공간적 변화 특성고 조절 요인. Ocean and Polar Res., 29, 135-153 https://doi.org/10.4217/OPR.2007.29.2.135
  14. 임동일, 김영옥, 강미란, 장풍국, 신경순, 장만. 2007b. 한국 남해 마산만에서 수질환경의 계절적 변동과 기초생산 제한인자. Ocean and Polar Res., 29, 346-366 https://doi.org/10.4217/OPR.2007.29.4.349
  15. 정해진, 박종규, 최현용, 양재삼, 심재형, 신윤근, 이원호, 김형섭, 조경제. 2000. 전남 고흥 해역의 유해성 적조의 발생연구 2: 1997년도 식물플랑크톤의 시공간적 변화. 한국해양학회지 바다, 5, 27-36
  16. 최진용, 박용안. 1998. 하계동안 한국 서해 태안반도 연근해에서 부유퇴적물의 운반양상. 한국해양학회지 바다, 3, 45-52
  17. 최중기. 1990. 경기만의 조석전선 형성과 생물학적 중요성에 관한 연구. 한국과학재단 보고서. 447p
  18. 최중기. 1991. 황해 중-동부 연안 수역의 조석전선이 식물플랑크톤 생산력과 분포에 미치는 영향. 한국해양학회지, 26, 223-241
  19. 최현용, 이상호, 오임상. 1998. 황해 중부 연안 수온전선역의 정량적 해석. 한국해양학회지 바다, 3, 1-8
  20. 최현용, 이상호, 유광우. 1999. 금강 하구언 대량방류시 황해중동부 해역의 염분 분포. 한국해양학회지 바다, 4, 1-9
  21. Billen, G., C. Lancelot, and M. Mayberk. 1991. N, P, Si retention along the aquatic continuum from land to ocean. p. 19-44. In: Ocean Margin Processes in Global Change, ed. by R.F.C. Matoura, J.M. Martin, and R. Wollast. John Wiley & Sons, New York
  22. Cugier, P., G. Billen, J.F. Guillaud, J. Garnier, and A. Menesguen. 2005. Modelling the eutrophication of the Seine Bight (France) under historical, present and guture riverine nutrient loading. J. Hydrol., 304, 381-396 https://doi.org/10.1016/j.jhydrol.2004.07.049
  23. Goni, M.A., N. Monacci, R. Gisewhite, A. Ogston, J. Crockett, and C. Nittrouer. 2006. Distribution and sources of particulate organic matter in the water column and sediments of the Fly River Delta, Gulf of Papua (Papua New Guinea). Estuar. Coast. Shelf Sci., 69, 225-245 https://doi.org/10.1016/j.ecss.2006.04.012
  24. Humborg, C., V. Ittekkot, A. Cociasu, and B.V. Bodungen. 1997. Effect of Danube River dam on Black Sea biogeochemistry and ecosystem structure. Nature, 386, 385-388 https://doi.org/10.1038/386385a0
  25. Justic, D., N.N. Rabalais, and R.E. Turner. 1995. Stoichiometric nutrient balance and Origin of coastal eutrophication. Mar. Pollut. Bull., 30(1), 41-46 https://doi.org/10.1016/0025-326X(94)00105-I
  26. Seung, Y.H., J.H. Chung, and Y.C. Park. 1990. Oceanographic studies related to the tidal front in the mid-Yellow Sea off Korea: Physical aspects. J. Oceanol. Soc. Korea, 25, 84-95
  27. Pingree, R.D., G.R. Forster, and G.K. Morrison. 1978. Turbulent convient tidal front. J. Mar. Biol. Ass. U.K. 54, 469-479 https://doi.org/10.1017/S0025315400058653
  28. Pingree, R.D., G.T. Mardell, and L. Maddock. 1983. A marginal front in Lyme Bay. J. Mar. Biol. Ass. U.K. 63, 9-15 https://doi.org/10.1017/S0025315400049754
  29. Simpson, J.H., D.J. Edelsten, A. Edwares, N.C.G. Morris, and P.B. Tett. 1982. The Islay Front: Physical structure and phytoplankton distribution. Estur. Coast. Mar. Sci., 9, 713-726 https://doi.org/10.1016/S0302-3524(79)80005-5
  30. Yoshida, Y. 1973. Changes in biological production in low trophic levels. p. 92-103. In: Fisheries Science Series, 1. Koseisha Koseikaku, Tokyo
  31. Wasmund, N., A. Andrushaitis, E. Lysiak-Pastuszak, B. Muller-Karulis, G. Nausch, T. Neumann, H. Ojaveer, I. Olenina, L. Postel, and Z. Witeek. 2001. Trophic status of the South-Eastern Baltic Sea: A comparison of coastal and open areas. Estur. Coast. Shel. Sci., 53, 849-864 https://doi.org/10.1006/ecss.2001.0828
  32. Wong, G.T.F., G.C. Gong, K.K. Liu, and S.C. Pai. 1998. Excess nitrate in the East China Sea. Estuar. Coast. Shelf. Sci., 46, 411-418 https://doi.org/10.1006/ecss.1997.0287

피인용 문헌

  1. Environmental Characteristics of Seawater and Sediment in Mariculture Management Area in Ongjin-gun, Korea vol.19, pp.6, 2013, https://doi.org/10.7837/kosomes.2013.19.6.570
  2. Variation of Nutrients due to Long-Term Effects of Ocean Dumping and Spatial Variability of Water Quality Parameters in Summer at the Ocean Waste Disposal Site Off the West Coast of Korea vol.22, pp.11, 2013, https://doi.org/10.5322/JESI.2013.22.11.1389