본문 바로가기
HOME> 논문 > 논문 검색상세

논문 상세정보

한국수산학회지 = Journal of the Korean Fisheries Society v.35 no.4, 2002년, pp.386 - 394   피인용횟수: 3

패류양식해역 환경용량 산정 모델 구축 -I . 모델 검정 및 민감도 분석-
Modification of an Ecosystem Model for Carrying Capacity of Shellfish System -I . Validation and Sensitivity Analysis-

이원찬   (국립수산과학원 환경관리과CC0187399  ); 김형철   (국립수산과학원 환경관리과CC0187399  ); 최우정   (국립수산과학원 환경관리과CC0187399  ); 이필용   (국립수산과학원 환경관리과CC0187399  ); 구준호   (국립수산과학원 환경관리과CC0187399  ); 박청길   (부경대학교 환경공학과UU0000598  );
  • 초록

    패류 양식 해역의 서식 환경과 양식 생물간의 상호 관계를 파악하고 지속적인 생산 방안을 위하여 굴 성장과 관련된 생리 대사 과정인 섭이, 소화, 배설, 호홉 등의 제 인자를 수식화하여 기존에 개발된 생태계모델 (EUTRP2)에 연계하여 환경용량 산정 모델을 구축하였다. 구축된 모델이 굴 성장과 서식환경과의 상호관계를 재현함에 있어 타당성 여부를 검정한 결과, 굴 성장에 따른 서식환경 중 식물플랑크톤 현존량이 감소하고 영양염 농도가 증가하는것으로 보아, 패류양식해역의 생태계 환경관리를 위한 도구로 사용할 수 있는 것으로 나타났다. 그리고, 생태계 구성 요소에 영향을 미치는 생물 인자에 대한 민감도 분석 결과, 구성 요소들은 식물플랑크톤의 증식 속도와 높은 민감도를 보였고, 굴 성장의 경우 동물플랑크톤 최대 섭이 속도와는 민감도가 낮은 반면, 식물플랑크톤 증식 속도, 사멸 속도와 굴의 먹이 흡수 효율에 매우 민감하였다.


    Carrying capacity model focused on interactions between the filter-feeder growth and their environments is presented, and differences among existing various carrying capacity models are reviewed. For carrying capacity modeling of shellfish system, we constructed a new numerical model coupled oyster growth model with an ecosystem model (EUTRP2). Physical and biological processes such as water transport and mixing, primary production, feeding and growth of the cultivated oyster, Crassostrea gigas and benthic-pelagic exchange were included in the model, Simulated results for validation showed that the more phytoplankton biomass decreased, the more oyster meat weight and nutrients increased, suggesting a powerful tool for reasonable management of shellfish aquaculture. The model was sensitive to parameters controlling the primary production. Among the ecosystem compartments, the oyster growth is highly influenced by small changes in the physiological parameters of phytoplankton and oyster. This sensitivity analysis indicated the importance of experimental data on biological parameters for calibration of the model.


  • 주제어

    Carrying capacity model .   Ecosystem model .   Oyster growth model .   Shellfish system .   Validation .   Sensitivity analysis.  

  • 참고문헌 (61)

    1. Asmus, H., R. Asmus and K. Reise. 1990. Exchange processes in an intertidal mussel bed: A Sylt-flume study in the Wadden Sea. Ber. Biol. Anst. Helgoland, 6, 1-79 
    2. Bacher, C., H. Bioteau and A. Chapelle. 1995. Modelling the impact of a cultivated oyster population on the nitrogen dynamics: The Thau lagoon case (France). Ophella, 42, 29-54 
    3. Bacher, C., P. Duarte, J.G. Feneira, M. He'ral and O. Raillard. 1998. Assessment and comparison of the Marennes-Ole'ron Bay (France) and Carlingford Lough (Ireland) cariying capacity with ecosystem models. 1998. Aquatic Ecology, 31, 379-394 
    4. Bayne, B.L. 1998. The physiology of suspension feeding by bivalve molluscs: An introduction to the Plymouth 'TROPHEE' workshop. J. Exp. Mar. Biol. Ecol., 219, 1-19 
    5. Bernard, F.R., 1974. Annual biodeposition and gross energy budget of mature Pacific oyster, Crassostrea gigas. J. Fish. Res. Board Canada, 31, 185-190 
    6. Boucher, G. and R. Boucher-Rodoni. 1988. In site measurement of respiratory metabolism and nitrogen fluxes at the interface of oyster beds. Mar. Ecol. Prog. Ser., 44, 229-238 
    7. Brown, T.N. and D. Kulasiri. 1996. Validating models of complex, stochastic, biological systems. Ecol. Model., 86, 129-134 
    8. Chapelle, A., A. Menesguen, J.M. Deslous-Paoli, P. Souchu, N. Mazouni, A. Vaquer and B. Millet. 2000. Modelling nitrogen, primary production and oxygen in a Mediterranean lagoon. Impact of oysters farming and inputs from the watershed. Ecol. Model., 127, 161-181 
    9. Choi, W.J., C.K. Park and S.M. Lee. 1994. Numerical simulation of the formation of oxygen deficient water-masses in Jinhae Bay. J. Kor. Fish. Soc., 27, 413-433 (in Korean) 
    10. Choi, W.J., Y.Y. Chun, J.H. Park and Y.C. Park. 1997. The influence of environmental characteristics on the fatness of Pacific oyster, Crassostrea gigas, in Hansan-Koje Bay. J. Kor. Fish. Soc., 30, 794-803 (in Korean) 
    11. Clemmesen, B. and C.B. Jorgensen. 1987. Energetic coasts and efficiencies of ciliary filter feeding. Mar. Biol., 94, 445-449 
    12. Dame, R.F. 1972. The ecological energies of growth, respiration and assimilation in the intertidal American oyster Crassotrea virginica. Mar. Biol., 17, 243-250 
    13. Dame, R.F. 1993. The role of bivalve filter feeder material fluxes in estuarine ecosystem. In Bivalve Filter Feeders in Estuarine and Coastal Ecosystem Processes, R.F. Dame, ed. NATO ASI Series, Springer-Verlag, New York, pp. 245-269 
    14. Di Toro, D.M., D.J. O'Connor and R.V. Thomann. 1971. A dynamic model of the phytoplankton population in the Sacramento-SanJoaquin Delta. Adv. Chem. Ser., 106, 131-180 
    15. Doering, P.H. and C.A. Oviatt. 1986. Application of filtration rate models to field populations of bivalves: An assessment using experimental mesocosms. Mar. Ecol. Prog. Ser., 31, 265-275 
    16. Dowd, M. 1997. On predicting the growth of cultured bivalves. Ecol. Mod., 104, 113-131 
    17. Eppley, R.W., J.N. Rogers and J.J. MaCarthy. 1969. Half saturation constants for uptake of nitrate and ammonium by marine phytoplankton. Limnol. Oceanogr., 14, 912-920 
    18. Eppley, R.W. 1972. Temperature and phytoplankton growth in the sea. Fish. Bull., 70, 1063-1082 
    19. Frost, B.W. 1972. Feeding behaviour of Calanus pacificus in mixtures of food particles. Limnol. Oceanogr., 17, 805-815 
    20. Gerritsen, J., A.F. Holland and D.E. Irvine. 1994. Suspension-feeding bivalves and the fate of primary production: An estuarine model applied to Chesapeake Bay. Estuaries, 17, 403-416 
    21. Grant, J., M. Dowd, K. Thompson, C. Emerson and A. Hatcher. 1993. Perspectives on field studies and related biological models of bivalve growth and carrying capacity. In Bivalve Filter Feeders in Estuarine and Coastal Ecosystem Process, R.F. Dame, ed. NATO ASI Series, Springer-Verlag, New York, pp. 371-420 
    22. H$\'{e}$ral, M., B.J. Rothschild and P. Goulletquer. 1990. Decline of oyster production in the Maryland portion of the Chesapeake Bay: Causes and perspectives. ICES Shellfish Committee K:20, 37p 
    23. H$\'{e}$ral, M. 1993. Why carring capacity models are useful tools for management of bivalve molluscs culture. In Bivalve Filter Feeders in Estuarine and Coastal Ecosystem Processes, R.F. Dame, ed. NATO ASI Series, Springer-Verlag, New York, pp. 455-478 
    24. Hibbert, C.J. 1977. Growth and survivorship in a tidal-flat population of the bivalve Mercenaria meivenana from Southampton Water. Mar. Biol., 44, 71-76 
    25. Hoch, T. and A. Menesguen. 1997. Modelling the biogeochemical cycles of elements limiting primary production in the English Channel II. Sensitivity analyses. Mar. Ecol. Prog. Ser., 146, 189-205 
    26. Ishikawa, M. and H. Nishimura. 1983. A new method of evaluating the mineralization of paticulate and dissolved photoassimilated organic matter. J. Oceanogr. Soc. Japan., 39, 29-42 
    27. J$\phi$rgensen, S.E. (ed.). 1979. Handbook of Environmental Data and Ecological Parameters. International society for ecological model-ling. Pergamon Press, New York, 1162pp 
    28. Kang, C.K., M.S. Park, P.Y. Lee, W.J. Choi and W.C. Lee. 2000. Seasonal variations in condition, reproductive activity and biochemical composition of the Pacific oyster, Crassostrea gigas (Thunberg), in suspended culture in two coastal bays of Korea. J. Shellfish Res., 19, 771-779 
    29. Kim, Y.S. 1980. Efficiency of energy transfer by a population of the farmed Pacific oyster, Crassostrea gigas in Geoje-Hansan Bay. Bull. Kor. Fish. Soc., 13, 179-193 (in Korean) 
    30. Kleijnen, J.P.C. 1995. Theory and methodology: Verification and validation of simulation models. European J. Operational Res., 82, 145-162 
    31. Klinck, J.M., E.N. Powell, E.E. Hofmann, E.A. Wilson and S.M. Ray. 1992. Modeling oyster populations: The effect of density and food supply on production. Pro. Adv. Mar. Tech. Conf., 5, 85-105 
    32. Kobayashi, M., E.E. Hofmann, E.N. Powell, J.M. Klink and K. Kusaka. 1997. A population dynamics model for the Japanese oyster, Crassostrea gigas. Aquaculture, 149, 285-321 
    33. Kusuki, Y. 1977. Fundamental studies on the deterioration of oyster growing grounds II. Organic content of faecal materials. Bull. Jpn. Soc. Sci. Fish., 43, 167-171 (in Japanese) 
    34. Marshall, S.M. and A.P. Orr. 1955a. Experimental feeding of the copepod Calanus finmarchicus on phytoplankton cultures labeled with radioactive carbon. Pap. Mar. Biol. Oceanogr., Deep-Sea Res., 3, 110-114 
    35. Marshall, S.M. and A.P. Orr. 1955b. On the biology of Calanus finmarchicus. VIII. Food uptake, assimilation and excretion in adult and stage V. Calanus. J. Mar. Biol. Asso. UK., 34, 495-529 
    36. Nakata, K., K. Ishikawa and Y. Matukawa. 1985. Numerical models of coastal current and transport in the bay. Bull. Coastal Oceanogr., 22, 96-108 (in Japanese) 
    37. Law, A.M. and W.D. Kelton. 1991. Simulation Modeling and Analysis. 2nd ed., McGraw-Hill, New York, 299pp 
    38. Lee, W.C. 2001. Modification and Application of an Ecosystem Model for Carrying Capacity in Oyster Culturing Ground. Ph. D. Thesis. Pukyong Univ., 132pp (in Korean) 
    39. Newell, R.I.E. and S.J. Jordan. 1983. Preferential ingestion of organic material by the American oyster Crassotrea virginica. Mar. Ecol. Prog. Ser., 13, 47-53 
    40. Ogura, N. 1975. Decomposition of dissolved organic matter in coastal seawater. Mar. Biol., 31, 101-111 
    41. Powell, E.N. and R.J. Stanton. 1985. Estimating biomass and energy flow of molluscs in palaeocommunities. Palaeontology, 28, 1-34 
    42. Powell, E.N., E.E. Hofmann, J.M. Klink and S.M. Ray. 1992. Modelling oyster populations. I. A commentary on filteration rate. Is faster always better? J. Shellfish Res., 11, 387-398 
    43. Prins, T.C., A.C. Smaal and R.F. Dame. 1998. A review of the feedbacks between bivalve grazing and ecosystem processes. Aquat. Ecol., 31, 349-359 
    44. Raillard, O., J.M. Deslous-Paoli, M. Heral and D. Razet. 1993. Model-ling growth and feeding of the Japanese oyster Crassostrea gigas in Marennes-Oleron Bay (France). Oceanolog. Acta., 16, 73-82 (in French) 
    45. Raillard, O. and A. M$\'{e}$nesguen. 1994. An ecosystem box model for estimating the carrying capacity of a macrotidal shellfish system. Mar. Ecol. Prog. Ser., 115, 117-130 
    46. Ross, A.H. and R.M. Nisbet. 1990. Dynamic models of growth and reproduction of the mussel, Mytilus edulis L. Functional Ecology, 4, 777-787 
    47. Rykiel, E.J. 1996. Testing ecological models: The meaning of validation. Ecol. Model., 90, 229-244 
    48. Ryther, J.H. 1956. Photosynthesis in the ocean as a function of light intensity. Limnol. Oceanogr., 1, 61-70 
    49. Salas, H.J. and R.V. Thomann. 1978. A steady-state phytoplankton model of Cheaspeake Bay. J. WPCF, 50, 2752-2770 
    50. Schnoor, J.L. 1996. Environmental Modeling: Fate and Transport of Pollutants in Water, Air, and Soil. A Wiley-Interscience Publication, John Wiley & Sons Inc., pp. 9-11 
    51. Scholten, H. and A.C. Smaal. 1998. Response of Mytilus edulis L. to varying food concentration: Testing EMMY, an ecophysiological model. J. Exp. Mar. Biol. Ecol., 219, 217-239 
    52. Shumway, S.E. 1982. Oxygen consumption in oysters: An overview. Mar. Biol. Lett., 3, 1-23 
    53. Smaal, A.C. 1991. The ecology and cultivation of mussels: New advances. Aquaculture, 94, 245-261 
    54. Smaal, A.C., T.C. Prince, N. Dankers and B. Ball. 1998. Minimum requirements for modelling bivalve carrying capacity. Aquat. Ecol., 31, 423-428 
    55. Smayda, T.J. 1970. Suspension and sinking of phytoplankton in the sea. Oceanogr. Mar. Biol. Ann. Rev., 8, 354-411 
    56. Soniat, T.M., S.M. Ray and L.M. Jeffrey. 1984. Components of the seston and possible available food for oysters in Galveston Bay, Texis. Contriv. Mar. Sci., 27, 127-141 
    57. Soniat, T.M. and S.M. Ray. 1985. Relationships between possible available food and the competition, condition and reproductive state of oysters from Galveston Bay, Texas. Contriv. Mar. Sci., 28, 109-121 
    58. Steele, J.H. 1974. The Structure of Marine Ecosystems. Cambridge, Mass., Harvard University Press, pp. 1-128 
    59. Sugawara, Y. and K. Okoshi. 1991. An important problem for oyster farming in enclosed coastal waters. Mar. Pollut. Bull., 22, 271-274 
    60. Suschenya, L.M. 1970. Food rations, metabolism and growth of crustaceans. In Marine Food Chains, J.H. Steele, ed. University of California Press, Berkeley, CA 
    61. Walne, P.R. 1972. The influence of current speed, body size and water temperature on the filtration rate of Give species of bivalves. J. Mar. Biol. Assoc. U.K., 52, 345-374 
  • 이 논문을 인용한 문헌 (3)

    1. KANG Yun Ho 2003. "Carrying Capacity and Fishery Resources Release in the Bangjukpo Surfzone Ecosystem" 한국수산학회지 = Journal of the Korean Fisheries Society, 36(6): 669~675     
    2. Lim, Weol-Ae ; Lee, Young-Sik ; Kang, Young-Sil ; Kim, Seong-Soo ; Kim, Seong-Hyun ; Choi, Hye-Sung ; Hur, Young-Baek ; Lee, Tae-Seek ; Lee, Jae-Young 2010. "Inter-annual Variation of Phytoplankton Community Structure in Aquacultural Areas of Tongyeong, SE Coastal Waters of Korea" 바다 : 한국해양학회지, 15(4): 158~165     
    3. Lee, Won-Chan ; Cho, Yoon-Sik ; Hong, Sok-Jin ; Kim, Hyung-Chul ; Kim, Jeong-Bae ; Lee, Suk-Mo 2011. "Estimation of Ecological Carrying Capacity for Oyster Culture by Ecological Indicator in Geoje-Hansan Bay" 海洋環境安全學會誌 = Journal of the Korean society of marine environment & safety, 17(4): 315~322     

 저자의 다른 논문

  • 이원찬 (23)

    1. 1999 "Nutrients and Phytoplankton Blooms in the Southern Coastal Waters of Korea: I. The Elemental Composition of C, N, and P in Particulate Matter in the Coastal Bay Systems" Journal of the Korean Society of Oceanography 34 (2): 86~94    
    2. 2002 "굴 양식수역의 환경용량 산정 -I. 생태계 모델을 이용한 거제 · 한산만 굴 먹이 공급량 추정" 한국수산학회지 = Journal of the Korean Fisheries Society 35 (4): 395~407    
    3. 2002 "굴 양식수역의 환경용량 산정 -II. 거제 · 한산만의 환경용량-" 한국수산학회지 = Journal of the Korean Fisheries Society 35 (4): 408~416    
    4. 2004 "해상 어류가두리양식장의 환경영향평가: I. 퇴적물 산소소모율 및 저서동물을 이용한 유기물 오염영향권 추정 및 유기탄소 순환" 바다 : 한국해양학회지 9 (1): 30~39    
    5. 2004 "해상 어류가두리양식장의 환경영향 평가: II. 가두리 양식장 퇴적물의 산소-황화수소 경계면에서 황화수소의 산화율 및 무산소 퇴적층에서 황산염 환원율 추정" 바다 : 한국해양학회지 9 (2): 64~72    
    6. 2004 "GIS를 이용한 양식어장 정보관리 시스템 구축" 한국지리정보학회지 = Journal of the Korean Association of Geographic Information Studies 7 (3): 90~98    
    7. 2004 "해수유동모델 결과의 3차원 가시화를 위한 GUI 구현" 한국지리정보학회지 = Journal of the Korean Association of Geographic Information Studies 7 (3): 99~107    
    8. 2005 "하수처리장 개선이 마산만 수질에 미치는 영향분석" 한국환경과학회지 = Journal of the environmental sciences 14 (8): 777~783    
    9. 2005 "수치모델을 이용한 해상어류가두리양식장의 환경관리 방안" 바다 : 한국해양학회지 10 (4): 181~195    
    10. 2007 "생태계 모델을 이용한 진해만의 COD의 거동과 분포특성 평가" 한국환경과학회지 = Journal of the environmental sciences 16 (12): 1369~1382    
  • 김형철 (14)

  • 구준호 (8)

  • 박청길 (33)

 활용도 분석

  • 상세보기

    amChart 영역
  • 원문보기

    amChart 영역

원문보기

무료다운로드
  • NDSL :
유료다운로드

유료 다운로드의 경우 해당 사이트의 정책에 따라 신규 회원가입, 로그인, 유료 구매 등이 필요할 수 있습니다. 해당 사이트에서 발생하는 귀하의 모든 정보활동은 NDSL의 서비스 정책과 무관합니다.

원문복사신청을 하시면, 일부 해외 인쇄학술지의 경우 외국학술지지원센터(FRIC)에서
무료 원문복사 서비스를 제공합니다.

NDSL에서는 해당 원문을 복사서비스하고 있습니다. 위의 원문복사신청 또는 장바구니 담기를 통하여 원문복사서비스 이용이 가능합니다.

이 논문과 함께 출판된 논문 + 더보기