Korean Journal of Ecology and Environment (생태와환경)

The Korean Society of Limnology (한국수생태학회)
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Comparison of Larval Fish Survival of Pale chub (Zacco platypus) Exposed to Different Levels Turbidity

탁수조건에 따른 피라미 치자어의 생존률 비교

  • Moon, Woon-Ki (Chungrok Environmental Ecosystem Research Institute) ;
  • Bae, Dae-Yul (Chungrok Environmental Ecosystem Research Institute) ;
  • Jung, Myoung-Sook (Water Environmental Engineering Research Division, NIER) ;
  • Lee, Sang-Don (Department of Environmental Science and Engineering, Ewha Womens University) ;
  • Kim, Jai-Ku (Chungrok Environmental Ecosystem Research Institute)
  • 문운기 ((주)청록환경생태연구소) ;
  • 배대열 ((주)청록환경생태연구소) ;
  • 정명숙 (국립환경과학원 물환경공학연구과) ;
  • 이상돈 (이화여대 환경.식품공학부) ;
  • 김재구 ((주)청록환경생태연구소)
  • Received : 2012.05.30
  • Accepted : 2012.09.04
  • Published : 2012.09.30
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Abstract

To quantitatively assess the effects of turbidity on egg development and larval fish survival, a laboratory fish rearing experiment was applied to different life stages (newly hatched larval stage, juvenile stage and pre-adult stage) of the Zacco platypus, one of the most universal and tolerant species in Korea. According to the stress index of turbidity in water with exposure time, three different treatments, including a reference condition (1~7 NTU) as well as intermediate (20~150 NTU) and high turbidity conditions (400~1,000 NTU) were applied, and egg hatching and larval fish mortality rates were observed. The mortality rates of newly hatched larval fish were significantly different among treatments (ANOVA, $F_{2,3}$=17.79, p<0.05). Average rates of survival to hatching were 20.9% (${\pm}0.1%$) for reference condition, 11% (${\pm}6.9%$) for intermediate level and 3.2% (${\pm}3.7%$) for high level conditions, respectively. A sudden change of mortality at the high level was observed within 5 days of the experiment. About 84% of juvenile fish survived until 20 experimental periods under conditions of reference turbidity, while survival under conditions of intermediate turbidity was over 80% of larval fish until day 13 of the experiment, but dropped to less than 10% after day 14 and 15 of two experiments. Fish mortality appeared from day 6 of the high turbidity experiment, and 50% mortality was achieved at day 9 to 10 of experiment. Full mortality occurred at day 14 of the experiment (RM-ANOVA, $F_{2,38}$, p<0.005). In the pre-adult stage experiment, no mortality was observed during the experiment at reference level treatment (20 days), while only slight mortality rates were observed for both intermediate and high levels until day 5 of the experiment, however, no further fish died in either experiment. It was significantly different compared to reference condition (RM-ANOVA, $F_{2,20}$=8.28, p<0.01), but no difference was observed between intermediate and high level conditions. Consequently, this tolerant species has been determined to be well adapted to high levels of turbidity in its adult stage, but more vulnerable throughout earlier life stages.

본 연구에서는 탁수농도에 따라 생물서식지에 영향을 주는 스트레스 지수를 활용하여 탁수에 대한 어류영향실험을 수행하였다. 국내 하천에서 우점비율이 가장 높은 피라미를 대상으로 발생단계별로 탁수에 대한 모의실험을 수행한 결과 발생 초기단계에서는 탁수에 대한 반응이 민감하게 나타났지만 성체단계에 이르면서 고탁수에 대한 적응하는 것으로 나타났다. 그 외 어종에 대한 탁수반응은 어종별 내성도에 따라 다르게 나타난다. 따라서 본 연구결과는 향후 수생태 건강성평가와 연계하여 하천의 건강성상태를 결정한 후, 평가등급에 따라 탁수에 대한 농도와 배출 허용기간을 적용하는데 유용한 지표가 될 것으로 기대한다.

Keywords

References

  1. Alabaster, J.S. 1972. Suspended solids and fisheries. Proceedings of the Royal Society of London Biological Sciences 180: 395-406.
  2. Alabaster, J.S. and R. Lloyd. 1980. Water quality criteria for freshwater fish. Butterworth, London.
  3. Bond, C.E. 1979. Biology of fishes. W.B. Saunders. Philadelpia.
  4. Choi, K.C. and W.K. Lee. 1994. One-hundred freshwater fishes in Korea. Hyeonam Publishing. Seoul, 531pp.
  5. Chung, S.W., H.S. Lee, S.W. Yoon, L. Ye, J.H. Lee and C.O. Choo. 2007. Characterization of physical properties of turbid how in the Daecheong reservoir watershed dining floods. Journal of Korean Society on Water Quality 23(6): 934-944. (in Korean)
  6. DFO. 1983. A rational for the suspended solids standards for Yukon streams subject to placer mining. Report to Interdepartmental Committee on Placer Mining, New Westminster, Canada.
  7. EIFAC (European Inland Fisheries Advisory Commission). 1964. Water quality criteria for European freshwater fish: report on finely divided solids and inland fisheries. United Nations, Food and Agriculture Organization, EIFAC Technical Paper 1, Rome, Italy.
  8. Herbert, W.M. and J.C. Merkens. 1961. The effect of suspended mineral solids on the survival of trout. International Journal of Air and Water Pollution 5: 46-55.
  9. Herbert, W.M. and J.M. Richards. 1963. The growth and survival of fish in some suspensions of solids of industrial origin. International Journal of Air and Water Pollution 7: 297-302.
  10. Hill, R.D. 1974. Mining impacts on trout habitat. Pages 47- 57 in Proceedings of a symposium on trout habitat research and management. Appalachian Consortium Press, Boone, North Carolina.
  11. Kim, B. and S. Jung. 2007. Turbid storm runoffs in Lake Soyang and their environmental effect. Korean Society of Environmental Engineers 29(11): 1-6. (in Korean)
  12. Kim, J.H., J. Seo, Y.E. Na and K.G. An. 2007a. Ecological health assessments on turbidwater in the downstream after a construction of Yongdam Dam. Korean Journal of Limnology 40(1): 130-142. (in Korean)
  13. Kim, J.K., J.S. Choi, Y.S. Jang, K.Y. Lee and B. Kim. 2007b. Effects of turbid water on fish community: Case studies of the Daegi stream and the Bongsan stream. Korean Journal of Limnology 40(3): 459-467. (in Korean).
  14. Langer, O.E. 1980. Effects of sedimentation on salmonid stream life. In Report on the technical workshop on suspended solids and the aquatic environment. Edited by K. Weagle. Department of Indian Affairs and Northern Development, Whitehorse, YT.
  15. Lawrence, M. and E. Scherer. 1974. Behavioral responses of whitefish and rainbow trout to drilling fluids. Fish. Mar. Ser. Tech. Rep. No. 502, Env. Canada.
  16. Lee, S.H., J.S. Choi, K.Y. Lee, Y.S. Jang, I.S. Lim, W.M. Heo, J.K. Kim and B. Kim. 2006. A study of water quality and fish community in lake Doam. Korean Journal of Limnology 39(2): 167-177. (in Korean)
  17. Mills, W.B., D.B. Porcella, M.J. Ungs, S.A. GhErini, K.V. Summers. 1985. Water quality assessment: a screening procedure for toxic and conventional pollutions in surface and ground water. USEPA, Report 600/6-85/0.02a, Athens, GA.
  18. Nakamura, M. 1969. Cyprinid fishes of Japan. Res. Inst. Natur. Res., Tokyo. 455pp. (in Japanese)
  19. NAS (National Academy of Sciences) and NAE (National Academy of Engineering). 1973,Water quality criteria 1972. U. S. Environmental Protection Agency, Ecological Research Series Report R3-73-033, Washington, D.C.
  20. Newcombe, C.P. and D.D. MacDonald. 1991. Effects of suspended sediments on aquatic ecosystems. North American Journal of Fisheries Management 11: 72-82. https://doi.org/10.1577/1548-8675(1991)011<0072:EOSSOA>2.3.CO;2
  21. Newcombe, C.P. and J.O.T. Jensen. 1996. Channel suspended sediment and fisheries: a synthesis for quantitative assessment of risk and impact. North American Journal of Fisheries Management 16: 693-727. https://doi.org/10.1577/1548-8675(1996)016<0693:CSSAFA>2.3.CO;2
  22. Newport, B.D. and J.E. Moyer. 1974. State-of-the art: sand and gravel industry. U.S.EPA, Report 660/2-74-066, Covallis, OR.
  23. Noggle, C.C. 1978. Behavioral, physiological and lethal effects of suspended sediment on juvenile salmonids. Master's thesis. University of Washington, Seattle, USA.
  24. Park, H.J. 2006. A study of the community fluctuation of benthic macroinvertebrates of the muddy water area and not muddy water area. MS thesis. Andong National University, Korea. (in Korean)
  25. Park, J.W., K.L. Lee, J.S. Choi and H.S. Kim. 2005. Dynamics of phytoplankton community after formation of turbid water in lake Imha. Korean Journal of Limnology 38(3): 429-434. (in Korean) Park, J.C., S.W. Jung, J.W. Park and H. Kim. 2008. Spatial and temporal dynamics of turbid water in hypolimnetic discharging reservoir (Andong), South Korea. Korean Journal of Limnology 41(3): 360-366. (in Korean)
  26. Park, J.C., S.W. Jung, J.W. Park and H. Kim. 2008. Spatial and temporal dynamics of turbid water in hypolimnetic discharging reservoir (Andong), South Korea. Korean Journal of Limnology 41(3): 360-366. (in Korean)
  27. Scullion, J. and R.W. Edwards. 1980. The effects of coal industry pollutants on the macro-invertebrate fauna of a small river in the South Wales Coalfield. Freshwater Biology 10: 141-162. https://doi.org/10.1111/j.1365-2427.1980.tb01189.x
  28. Shin, J.K., C.K. Kang and S.J. Hwang. 2003. Daily variations of water turbidity and particle distribution of high turbid-water in Paltang reservoir, Korea. Korean Journal of Limnology 36(3): 257-268. (in Korean).
  29. Shin, M.J., J.S. Kim, Y.H. Hwang, J.E. Lee and E.W. Seo. 2008. Effect of turbidity changes on tissues of Zacco koreanus. Korean Journal of Limnology 41(1): 73-80. (in Korean)
  30. Shin, W.K. 2005. Influence of turbidity on zooplankton dynamics in the Nakdong river. MS thesis. Pusan National University, Korea. (in Korean)
  31. Sigler, J.W., T.C. Bjornn and F.H. Everest. 1984. Effects of chronic turbidity on density and growth of steelhead and coho salmon. Transactions of the American Fisheries Society 113: 142-150. https://doi.org/10.1577/1548-8659(1984)113<142:EOCTOD>2.0.CO;2
  32. Slaney, P.A., T.G. Halsey and A.F. Tautz. 1977. Effects of forest harvesting practices on spawning habitat of stream salmonids in the Centennial Creek watershed, British Columbia. Province of British Columbia, Ministry of Recreation and Conservation, Fisheries Management Report 73: 45p.
  33. Stober, Q.J., B.D. Ross, C.L. Melby, P.A. Dinnel, T.H. Jagielo and E.O. Salo. 1981. Effects of suspended volcanic sediment on coho and chinook salmon in the Toutle and Cowlitz rivers. Fisheries Research Institute, University of Washington, Seattle. Technical Completion Report FRI-UW-8124.
  34. Wilber, C.G. 1969. The biological aspect of water pollution. Charles C. Thomas, Springfield, Illinois.
  35. Wilber, C.G. 1983. Turbidity in the aquatic environment: an environmental factor in fresh and oceanic waters. Charles C. Thomas, Springfield, Illinois.
  36. Zar, J.H. 1984. Biostatistical analysis 3rd ed. Prentice-Hall, New Jersey, 718pp.