한국환경생태학회지 (Korean Journal of Environment and Ecology)

  • 제25권5호
  • /
  • Pages.747-759
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  • 2011
  • /
  • 1229-3857(pISSN)
  • /
  • 2288-131X(eISSN)
한국환경생태학회 (Korean Society of Environment and Ecology)
권호 표지

Ecopath 모델을 이용한 남양호와 낙동강 하류 생태계의 영양구조 및 에너지 흐름 비교

Comparison of Trophic Structures and Energy Flows using the Ecopath Model in the Lake Namyang and the Lower Reaches of the Nakdong River

  • 장성현 (대구대학교 생물교육과) ;
  • 이정호 (대구대학교 생물교육과)
  • 투고 : 2010.10.20
  • 심사 : 2011.10.22
  • 발행 : 2011.10.31
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초록

Ecopath 모델을 이용하여 남양호와 낙동강 하류 생태계의 영양구조와 에너지 흐름을 정량적으로 파악하고, 그 결과를 비교 분석하고자 하였다. 이를 위해 2007년 갈수기(5월)와 풍수기(8월)에 남양호와 낙동강 하류 수계의 각 6개 지점에서 조사를 실시하였다. 연구결과, 남양호는 무생물인 유기쇄설물과 식물플랑크톤, 대형 수생식물 등이 생산자로, 동물플랑크톤과 저서동물, 떡붕어, 붕어, 기타 어류 등은 1차 소비자로, 잉어와 동자개는 2차 소비자로 조사되었으며, 낙동강 하류는 무생물인 유기쇄설물과 식물플랑크톤, 대형 수생식물 등은 생산자로, 동물플랑크톤과 저서동물, 기타 어류, 잉어, 누치 등은 1차 소비자로, 배스는 2차 소비자로 나타났다. 영양구조는 남양호가 1.0~3.3의 범위를, 낙동강 하류는 1.0~3.7의 범위로 낙동강 하류가 남양호보다 더 긴 먹이사슬을 가지는 것으로 추정되었다. 영양단계별 먹이자원에 대한 경쟁은 남양호가 0.100~0.900로 나타나 0.018~0.845 범위의 낙동강 하류보다 먹이자원에 대해 높은 경쟁을 가지는 것으로 확인되었다. 총에너지량은 남양호가 14.1 kg $m^{-2}$, 낙동강 하류는 2.7 kg $m^{-2}$이었으며, 이 중 남양호 수계는 39%(5440.919 g $m^{-2}$)는 섭식으로, 21%(3107.271 g $m^{-2}$)은 이출, 12%(1708.362 g $m^{-2}$)는 호흡, 28%(4018.551 g $m^{-2}$)은 유기쇄설물로 전환되는 것으로 나타났으며, 낙동강 수계는 52.0%(1433.998 g $m^{-2}$)은 섭식으로, 9.1%(252.101 g $m^{-2}$)은 이출, 18.0%(498.150 g $m^{-2}$)은 호흡, 20.9%(575.984 g $m^{-2}$)는 유기쇄설물로 전환되는 것으로 추정되었다.

The purpose of this study was to compare the trophic structures and the energy flows in the Lake Namyang and the lower reaches of the Nakdong River using the Ecopath model. The sampling and analyses were carried out at 6 sampling sites of the Lake Namyang and the lower reaches of the Nakdong River respectively on March and November in 2007. As a result, the Lake Namyang was consisted of producers(Detritus, Macrophytes, Phytoplankton), primary consumers(Zooplankton, Zoobenthos, Carassius cuvieri, Carassius auratus, Other fishes) and secondary consumer(Cyprinus carpio, Pseudobagrus fulvidraco) and the lower reaches of the Nakdong River was consisted of producers(Detritus, Macrophytes, Phytoplankton), primary consumers (Zooplankton, Zoobenthos, Cyprinus carpio, Hemibarbus labeo, Other fishes) and secondary consumer (Micropterus salmoides). The food-chain length of the Lake Namyang was relatively short when compared with the lower reaches of the Nakdong River. The shortness of food-chain length in the Lake Namyang could be attributed to the low biomass of the top predators. The total system throughput of the lake Namyang was estimated at 14.3 kg $m^{-2}\;year^{-1}$ including a consumption of 39.0%, exports of 21.0%, respiratory flows of 12.0% and flows into detritus of 28.0% and the total system throughput of the lower reaches of the Nakdong River was estimated at 2.8 kg $m^{-2}\;year^{-1}$ including a consumption of 52.0%, exports of 9.1%, respiratory flows of 18.0% and flows into detritus of 20.9% in the lower reaches of the Nakdong River.

키워드

참고문헌

  1. Allen, K.F.(1971) Relation between production and biomass. J. Fish. Res. Bd. Can. 20: 1573-1581.
  2. Angelini, R. and A.A. Agostinho(2005) Food web model of the Upper Parana River Flood plan in: description and aggregation effects. Ecological Modelling 181: 109-121. https://doi.org/10.1016/j.ecolmodel.2004.06.025
  3. Angelini, R., M.A.P. Abuabara and A.C. Rietzler(1996) Application of de Bernardi and Di Cola model in a Argyrodiaptomus furcatus(zooplankton-copepod) from Broa Reservoir(Aso Carlos SP-Brazil). Memorie dell'Istituto Italiano di Idrobiologia 54: 69-75.
  4. APHA(American Public Health Association), AWWA(American Water Works Association) and WEF(Water Environment Federation)(1998) Standard methods for examination of water and wastewater, 20th ed. American Public Health Association, Washington, D.C.
  5. Brey, T.(1999) A collection of empirical relations for use in ecological modelling Naga, The ICLARM Quarterly 22(3): 24-28.
  6. Brock, T.D.(1967) The ecosystem and the steady state. Bioscience 17:166-169. https://doi.org/10.2307/1293834
  7. Christensen, V. and D. Pauly(1993) On steady-state modelling of ecosystems. In: Trophic models of aquatic ecosystems, Christensen V, D Pauly eds. ICLARM Conference Proceedings 26, International Center for Living Aquatic Resources Management, Manila, Philippines.
  8. Christensen, V.(1995) Ecosystem maturity-towards quantification. Ecological Modelling 77: 3-32. https://doi.org/10.1016/0304-3800(93)E0073-C
  9. Christensen, V., C.J. Walters and D. Pauly(2000) Ecopath with Ecosim: A user's guide. Fisheries center. University of British Columbia, Vancouver and ICLARM, Malaysia.
  10. Fetahi, T. and S. Mengistou(2007) Trophic analysis of Lake Awassa(Etiopia) using mass-balance Ecopath model. Ecological modeling 201: 398-408. https://doi.org/10.1016/j.ecolmodel.2006.10.010
  11. Finn, J.T.(1976) Measurement of ecosystem structure and function derived from analysis of flows. Journal of Theoretical Biology 56: 363-380. https://doi.org/10.1016/S0022-5193(76)80080-X
  12. Fishbase(2007) http://www.fishbase.com.
  13. Hong, S.G., H.J. Kang, E.S. Kim, J.G. Kim, C.H. Kim E.J. Lee, J.C. Lee, J.S. Lee, B.S. Lim, Y.S. Jung and H.R. Jung(2005) Restoration ecology and engineering: conservation and management of habitats and ecotope. Lifescience, Seoul, 310pp. (in Korean)
  14. Jang, S.H.(2008) Analysis of trophic structure and energy flows using the Ecopath model in lake and stream ecosystem. Ph. D. thesis, Univ. of Daegu, Gyungsan, Korea, 113pp. (in Korean with English abstract)
  15. Jang, S.H., C.I. Zhang, J.H. Na and J.H. Lee(2008b) Analysis of trophic structures and energy flows in aquatic ecosystem of the lower reaches of the Nakdong River. Korean J. Environ. Biol. 26(4): 292-302. (in Korean with English abstract)
  16. Jang, S.H., C.I. Zhang, J.H. Na, S.W. Kim, K.G. An, J.J. Lee and J.H. Lee(2008a) A analysis of trophic structure in Lake Namyang using the Ecopath modeling. Korean J. Limnol. 41(2): 144-154. (in Korean with English abstract)
  17. Jones, J.G.(1979) A guide to methods for estimating microbial numbers and biomass in fresh water. Freshwater biological association, Scientific publication No. 39.
  18. Jones, R.(1984) Assessing the effects of changes in exploitation patterns using length composition data(with notes on VPA and cohort analysis). FAO Fisheries Technical Paper 256, 118pp.
  19. Kang, Y.H.(2003) Carrying capacity and fishery resource release in the Bangjukpo surf zone ecosystem. J. Kor. Fish. Soc., 36: 669-675. (in Korean with English abstract)
  20. Kang, Y.H.(2005) A preliminary trophic flow model for Gwangyang Bay, Korea. J. Kor. Fish. Soc. 38: 184-195. (in Korean with English abstract)
  21. Mihuc, T.B.(1997) The functional trophic role of lotic primary consumers: generalist versus specialist strategies. Freshwater Biol. 37: 455-462. https://doi.org/10.1046/j.1365-2427.1997.00175.x
  22. Ministry of Environment(2000) Standard method of water quality. Ministry of Environment, Seoul, 622pp.(in Korean)
  23. Odum, E.P.(1968) Energy flow in ecosystems-a historical review. American Zoology 8: 11-18.
  24. Park, C.C and M.W. Son(2007) Ecology Seoul. 332pp. (in Korean)
  25. Pauly, D.(1984) Fish population dynamics in tropical waters; manual for use with programmable calculators. ICLARM studies Rev. 8: 325.
  26. Pauly, D., V. Christensen and C. Walters(2000) Ecopath, Ecosim, and Ecospace as tools for evaluation ecosystem impact of fisheries. ICES J. Marine Sci. 57: 697-706. https://doi.org/10.1006/jmsc.2000.0726
  27. Sipauba-Tavares, L.H., M.A. Bachion and O. Rocha(1994) Estudo do crescimento populational de tres especies zooplanctonicas em laboratorio e o uso do plandcton na alimentacao de alevinos de Oerochromis niloticus(tilapia) e Astyanax scabripinis paranae( lambari). Rev. UNIMAR 16: 189-201.
  28. Takeda, A.Y., G.Y. Shimizu and J. Higuti(1997) Variacoes espaco-temporais da comunidade zoobentica. In: Vazzoler, A.E.M., Agostinho, A.A., Hahn, N.S.(Eds), Aplanicie de inundacao do alto rio Parana: aspectos fisicos, biologicos e socio- economicos. Ed. da Universidade Estadual de Maringa, pp. 157-177.
  29. Thomas, M.S. and L.S. Robert(2007) Elements of Ecology(6th). Lifescience, Seoul, 630pp. (in Korean)
  30. Ulanowicz, R.E. and C.J. Puccia(1990) Mixed trophic impacts in ecosystems. Coenoses 5: 7-16.
  31. Walters, C., V. Christensen and D. Pauly(1997) Structuring dynamics models of exploited ecosystems from trophic mass-balance assessments. Rev. Fish Bio. Fish. 7: 139-172. https://doi.org/10.1023/A:1018479526149
  32. Zhang, C.I. and S.C. Yoon(2003) Effects of climatic regime shift on the structure of marine ecosystem in the southwestern east sea during the 1970s. J. Kor. Fish. Soc. 36: 389-401. (in Korean with English abstract)
  33. Zhang, C.I.(1991) Fisheries resource ecology. Woosungsa, Seoul, 399pp. (in Korean)