Korean Journal of Fisheries and Aquatic Sciences (한국수산과학회지)

The Korean Society of Fisheries and Aquatic Science (한국수산과학회)
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A Quantative Population Dynamic Model for Estimating Damages in Fishery Production in the Benthic Ecosystem of Abalone Culture Grounds

전복양식장 저서생태계의 훼손으로 인한 어업자원의 생산감소량 추정 모델

  • KANG Yong Joo (Department of Marine Biology, Pukyong National University) ;
  • ZHANG Chang Ik (Department of Marine Production Management, Pukyong National University)
  • 강용주 (부경대학교 자원생물학과) ;
  • 장창익 (부경대학교 해양생산관리학과)
  • Published : 2003.08.01
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Abstract

Marine populations are maintained through the processes of spawning, growth, recruitment, natural death and fishing in a marine ecosystem. Based upon each of these processes, a quantitative population dynamic model was developed to estimate damages in fishery production due to accidents in a fishing ground. This model was applied for the abalone culture grounds in Korean waters. Three components of damages were identified in the ecosystem of the abalone culture grounds, namely, physical damages in the substratum of the fishing ground, biological damages in the structure and function of the ecosystem, and damages in fishery production. Considering these three components the processes and durations of damages in fishery production were determined. Because the abalone population is composed of multiple year classes, damages influence all the year classes in the population, when they occur The model developed in this study is: $$y=(n_{\lambda}+1){\times}Y_E\;-\;\sum\limits^{n_\lambda-n_c}_{l=0}\;y_{n_c/i}$$ where, y is the expected damages in fishery production during the period of restoration of the damaged abalony population, $Y_E$ is the annual equilibrium yield, $n_{\lambda}$ is the maximum age in the population, $t_s$ is the year of damage occurrence, $n_c$ is the age at recruitment, and $\sum\limits^{n_\lambda-n_c}_{l=0}\;y\;_{n_c/i}$ is total expected lifetime catch of year classes which were recruited during the restoration period.

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References

  1. Beverton, R.J.H. and S.J. Holt. 1957. On the dynamics of exploited fish populations. Fishery investigations, Series II, Marine Fisheries, Great Britain Ministry of Agriculture, Fisheries and Food, 19, 533 pp
  2. Chang S.D. and P. Chin. 1978. Effect of suspended silt and clay on the mortality of some species of bivalives. Bull. Kor. Fish. Soc., 11, 227-231. (in Korean)
  3. Choi, M.H. 2002. Integration of the feasibility assessment procedure and EIA of the big public investment project: in the case of the Saemangeum reclamation project. J. Kor. Soc. Environ. Impact, 11, 93-107. (in Korean)
  4. Choung, Y.S. and J.H. Kim. 1989. Clonal growth and shoot modules dynamics of Phyragmites longivalvis in a reclaimed land. Kor. J. Ecol., 12, 171-182. (in Korean)
  5. Choung, Y.S. and J.H. Kim. 1991. Studies on the population biology of some clonal plants in a coastal reclaimed land I. Rhizome architecture, patch formation and growth of Calamagrostis epigeios plants. Kor. J. Ecol., 14, 327-343. (in Korean)
  6. Hwang, M.l. 2000. Reclamation of tidal flats and environ-mental issues along western coast of Korea. J. Geo. Edu., 43, 61-67
  7. Jung, R.H., J.S. Hong and J.H. Lee. 1997. Spatial and seasonal patterns of polychaete community during the reclamation and dredging activities for the con-struction of the Pohang Steel Mill Company in Kwangyang Bay, Korea. J. Kor. Fish. Soc., 30, 730-743
  8. Kang, J.W. and N.P. Go. 1977. Marine Algae Culture. Taehwa Publishing Co. Busan, 294 pp. (in Korean)
  9. Kang, Y.J., K.S. Kim and K.L. Ha. 1997. A study on the estimation method of compensation for restriction in licensed fisheries caused by a large scale coastal reclamation. J. Fish. Busin. Admin., 27, 71-83. (in Korean)
  10. Kim, J.A., K.H. Cho and H.H.M. Lee. 2001. Vegetation structure of the Kungae reclaimed wetland in a coastal lagoon of East Sea, Korea. J. Kor. Ecol., 24, 27-34. (in Korean)
  11. Lee, K.S. J.Y. Park, J.B. Lee and J.C. Yoo. 1999. Wintering status of waterbirds in three reclaimed areas of the west coast of Korea. Bull. Kor. Inst. Ornithol., 7, 1-11
  12. Min, B.M. and J.H. Kim. 2000. Plant succession and interaction between soil and plants after land reclama-tion on the west coast of Korea. J. Plant BioI., 43, 41-47 https://doi.org/10.1007/BF03031035
  13. Park, J.S., Y.J. Kang and C.I. Zhang. A quantitative method for estimating damages in fishery production due to silt and clay in the tidal flat fishing grounds. J. Kor. Fish. Soc., 36(4), 402-408. (in Korean)
  14. Yoo S.J. and K.S. Shin. 1996. Oilspill damage assessment of natural fisheries resources by ecological models. J. Kor. Fish. Soc., 29, 174-190. (in Korean)
  15. Yoo, S.K. 2000. Shallow Water Aquaculture. 2nd Edition. Guduk Publishing Co. Busan. 639 pp. (in Korean)
  16. Yoo, H.B. and K.S. Kim. 1998. A comparative study of zooplankton communities in the inning reservoir groups. Wonkwang J. Environ. Sci., 7, 49-64. (in Korean)
  17. Zhang, C.I. 1991. Fisheries Resource Ecology. Woosung Publishing Co., Seoul, 399 pp. (in Korean)

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