Hydrodynamics and Its Effects on the Aquatic Ecosystem

  • L.C. Luo
  • B.Q. Qin
Part of the Monographiae Biologicae book series (MOBI, volume 87)

Keywords

Entropy Migration Phosphorus Chlorophyll Transportation 

Preview

Unable to display preview. Download preview PDF.

Unable to display preview. Download preview PDF.

Refrences

  1. Amos, C. L., G. R. Daborn, H. A. Christian, A. Atkinson & A. Robertson, 1992. In situ erosion measurements on fine-grained sediments from the Bay of Fundy. Marine Geology 108: 175–196.CrossRefGoogle Scholar
  2. Blom, G., E. H. S. Van Duin, R. H. Aalderink, L. Lijklema & C. Toet, 1992. Modelling sediment transport in shallow lakes: interactions between sediment transport and sediment composition. Hydrobiologia 235: 153–166.CrossRefGoogle Scholar
  3. Drago, M., L. Iovenitti, 2000. $\UPsigma$-Coordinates hydrodynamic numerical model for coastal and ocean three-dimensional circulation. Ocean Engineering 27: 1065–1085.CrossRefGoogle Scholar
  4. Durance, J. A. & D. G. Hughes, 1983. North Sea dynamics. Berlin: Springer-Verlag.Google Scholar
  5. Glenn, S. M. & W. D. Grant, 1987. A suspended sediment stratification correction for combined wave and current flows. Journal of Geophysical Research 92: 8244–8264.CrossRefGoogle Scholar
  6. Hawley, N., 2000. Sediment resuspension near the Keweenaw Peninsula, Lake Superior during the fall and winter 1990–1991. Journal of Great Lakes Research 26: 495–505.CrossRefGoogle Scholar
  7. Hu, W. P., P. M. Pu & B. Q. Qin, 1998a. A three-dimensional numerical simulation on the dynamics in Taihu Lake, China (I): the water level and the current during the 9711 typhoon process. Journal of Lake Sciences 10: 17–25 (In Chinese with English abstract).Google Scholar
  8. Hu, W. P., P. M. Pu & B. Q. Qin, 1998b. A three-dimensional numerical simulation on the dynamics in Taihu Lake, China (II): the typical wind-driven current and its divergence. Journal of Lake Sciences 10: 26–34 (In Chinese with English abstract).Google Scholar
  9. Hutter, K. 1983. Hydrodynamics of Lakes. International Center for Mechanical Sciences, CISM Courses Lectures No. 286. New York: Springer.Google Scholar
  10. Jiang, W., T. Pohlmann, J. Sündermann & S. Z. Feng, 2000. A modeling study of SPM transport in the Bohai Sea. Journal of Marine Systems 24: 175–200.CrossRefGoogle Scholar
  11. Krone, R. B., 1962. Flume studies of the transport of sediment in estuarial shoaling. Final Report. Hydraulic Engineering Laboratory and Sanitary Engineering Research Laboratory, University of California, Berkeley,120.Google Scholar
  12. Liang, R. J. & J. H. Zhong, 1994. A three-dimensional numerical simulation of wind-driven water current in Taihu Lake. Journal of Lake Sciences 6: 289–297 (In Chinese with English abstract).Google Scholar
  13. Lick, W., 1994. The flocculation, deposition, and resuspension of fine-grained sediments. In: DePinto, J. V., W. Lick & J. F. Paul (eds), Transport and transformation of contaminants near the sediment–water interface. London: Lewis Publishers,35–57.Google Scholar
  14. Lijklima, L., R. H. Aalderink, G. Blom & E. H. S. Van Duin, 1994. Sediment transport in shallow lakes: two case studies related to eutrophication. In: DePinto, J. V., W. Lick & J. F. Paul (eds), Transport and transformation of contaminants near the sediment-water interface. London: Lewis Publishers, 253–279.Google Scholar
  15. Liu, J. J., 1966. On the start-up of sediments under wave actions. Monographic Reviews on the Water Resources and Transportation 10: 1–9 (In Chinese with English abstract).Google Scholar
  16. Liu, Q. J., 1993. The data simulation of wind driven flow in Meiliang gulf of Lake Taihu. Master’s thesis, Nanjing Institute of Geography and Limnology, Chinese Academy of Sciences.Google Scholar
  17. Luo, L. C., 2004. Hydrodynamics and its effects on aquatic environment in Lake Taihu. Ph.D thesis, Nanjing Institute of Geography and Limnology, Chinese Academy of Sciences (In Chinese).Google Scholar
  18. Luo, L. C., B. Q. Qin, W. P. Hu & F. B. Zhang, 2004a. Wave characteristics in Lake Taihu. Journal of Hydrodynamics 19: 664–670.Google Scholar
  19. Luo, L. C., B. Q. Qin, G. W. Zhu, Y. L. Zhang & J. Ji, 2004b. Current circulation pattern in winter in Meiliang Bay, Lake Taihu. Journal of Lake Sciences 16: 73–76 (In Chinese with English abstract).Google Scholar
  20. Madale, R.V. & S. A. Piacsek, 1977. A semi-implicit numerical model for baroclinic oceans. Journal of Computational Physics 23:167–178.CrossRefGoogle Scholar
  21. Madsen, O. S., 1976. Wave climate of the continental margin: elements of its mathematical description. In: Stainley, J. D. & D. J. P. Swift (eds), Marine sediment transport and environmental management. New York:Wiley.Google Scholar
  22. Mehta, A. J., 1991. Characterization of cohesive soil bed surface erosion with special reference to the relationship between erosion shear strength and bed density. Coastal and Oceanographic Engineering Dept., University of Florida. UFL/COEL/MP-91/4.Google Scholar
  23. Mehta, A. J. & E. Partheniades, 1975. An investigation of the depositional properties of flocculated fine sediments. ASCE Journal of Hydraulics Research 13: 361–376.Google Scholar
  24. Mellor, G. L., 1998. Users guide for a three-dimensional, primitive equation, numerical ocean model. Princeton: Princeton University.Google Scholar
  25. Nanjing Institute of Geography, Chinese Academy of Sciences, 1965. Investigation of Lake Taihu. Beijing: SciencePress.Google Scholar
  26. Nielsen, P., S. Robert, B. Moller-Christiansen & P. Oliva, 2001. Infiltration effects on sediment mobility under waves. Coastal Engineering 42: 105–114.CrossRefGoogle Scholar
  27. Pang, Y. & P. M. Pu, 1995. Estimation of friction coefficient on the bottom of Taihu Lake. Shanghai Environmental Sciences 14: 34–35 (In Chinese with English abstract).Google Scholar
  28. Pang, Y. & P. M. Pu, 1996. Numerical simulation of three-dimensional wind-driven current in Taihu Lake. Acta Geographica Sinica 51: 328–332 (In Chinese with English abstract).Google Scholar
  29. Pang, Y., P. M. Pu, G. Gao & Q. Q. Wang, 1994. Numerical simulations and their verification with uniform wind stress in Taihu Lake. Transaction of Oceanology and Limnology 4: 9–15 (In Chinese with English abstract).Google Scholar
  30. Partheniades, E., 1977. Unified view of wash load and bed material. ASCE Journal of the Hydraulics Division 103: 1037–1050.Google Scholar
  31. Qiao, S. L., 1989. Estimation of the spectrum of wind waves in East Lake Taihu. Proceedings of Limnology and Oceanography Science. Beijing: Agricultural Press, 564–632.Google Scholar
  32. Qiao, S. L., J. M. Du, G. P. Chen & S. Zou, 1996. Calculation method and characteristics of wind-wave in lake. Journal of Nanjing Hydraulic Research Institute 3: 189–197 (In Chinese with English abstract).Google Scholar
  33. Qin, B. Q. & D. K. Stevens, 2001. A 3-D hydrodynamic model and its trial verification in water environment. Advances in Water Science 12:143–152 (In Chinese with English abstract).Google Scholar
  34. Qin, B. Q., W. P. Hu & W. M. Chen, 2004. Process and mechanism of water environment evolution in Lake Taihu. Beijing: Science Press (In Chinese).Google Scholar
  35. Qin, B. Q., W. P. Hu, W. M. Chen, J. Ji, C. X. Fan, Y. W. Chen, X. Y. Gao, L. Y. Yang, G. Gao, W. Y. Huang, J. H. Jiang, S. Zhang, Y. B. Liu & Z. Y. Zhou, 2000. Studies on the hydrodynamic processes and related factors in Meiliang Bay, Northern Taihu Lake, China. Journal of Lake Sciences 12: 325–334 (In Chinese with English abstract).Google Scholar
  36. Shanahan, P., R. A. Luettich & D. Harleman, 1991. Water quality modelling: application to lakes and reservoirs: a case study of Lake Balaton, Hungary. In: Henderson-Sellers, B. (ed), Water quality modeling, vol. IV. Decision support techniques for lakes and reservoirs. London: CRC Press, 69–114.Google Scholar
  37. Sheng, Y. P., 1982. >Modeling coastal currents and sediment transport. In: 18th Conference on Coastal Engineering, ASCE,14–19.Google Scholar
  38. Sheng, Y. P. & W. Lick, 1979. The transport and resuspension of sediments in a shallow lake. Journal of Geophysical Research 84(C4): 1809–1826.CrossRefGoogle Scholar
  39. Sun, W. H., 2001. The simulation study of wind-induced current and pollution zone of Lake Taihu. Master’s thesis, Hohai University, Nanjing.Google Scholar
  40. Vlag, D. P., 1992. A model for predicting waves and suspended silt concentration in a shallow lake. Hydrobiologia 236: 119–131.CrossRefGoogle Scholar
  41. Wang, Q. Q., 1987. A numerical simulation of wind-driven circulation in Taihu Lake. Journal of Hohai University 15(suppl 2): 11–17 (In Chinese with English abstract).Google Scholar
  42. Wang, Y. Q. & K. Hutter, 2001. Three-dimensional wind-induced baroclinic circulation in rectangular basins. Advances in Water Resources 24:11–27.CrossRefGoogle Scholar
  43. Wang, Q. Q., J. H. Jiang & P. M. Pu, 1992. Numerical simulations and their verifications with one station data of wind-driven surge and currents in Taihu Lake. Journal of Lake Sciences 4: 1–7 (In Chinese with English abstract).Google Scholar
  44. Wang, H. Z., Z. Y. Song & H. C. Xue, 2001. A quasi-3D numerical model of wind-driven current in Taihu Lake considering the variation of vertical coefficient of eddy viscosity. Journal of Lake Sciences 13: 233–239 (In Chinese with English abstract).Google Scholar
  45. Wen, S. C. and Z. W. Yu, 1984. Theory and computation of ocean waves. Beijing: Science Press (In Chinese).Google Scholar
  46. Wu, J. & P. M. Pu, 1989. Numerical simulations of the hydrodynamics of Taihu Lake by using the irregular-grid finite difference model. Memoirs of Nanjing Institute of Geography and Limnology Academia Sinica. Beijing, Science Press, 1–13 (In Chinese with English abstract).Google Scholar
  47. Zhang, W. H., 1992. A preliminary study on seiches in Taihu Lake. Journal of Lake Sciences 4: 23–28 (In Chinese with English abstract).Google Scholar
  48. Zhang, Q. Y., & K. Y. H. Gin, 2000. Three-dimensional numerical simulation for tidal motion in Singapore’s coastal waters. Coastal Engineering 39:71–92.CrossRefGoogle Scholar
  49. Zhang, J. S. & M. Xu, 2003. Sediment resuspension in Lake Taihu. Report of Nanjing Hydraulic Research Institute.Google Scholar
  50. Zhu, Y. H. & G. H. Fang, 1994. A 3D barotropic model on shelf and shallow sea and application to Bohai Sea, Yellow Sea, and East China Sea. Acta Oceanologica Sinica 16: 11–26 (In Chinese).Google Scholar
  51. Zhu, Y. C. & Q. M. Cai, 1998a. Studies on a three-dimensional hydro-dynamic model for Meiliang Bay, Taihu Lake I. Model description and result interpretation. Oceanologia et Limnologia Sinica 29: 79–85 (In Chinese with English abstract).Google Scholar
  52. Zhu, Y. C. & Q. M. Cai, 1998b. Studies on a three-dimensional hydro-dynamic model in Meiliang Bay, Taihu Lake II. The diffusion of nutrient salt under the action of three-dimensional currents. Oceanologia et Limnologia Sinica 29: 169–174 (In Chinese with English abstract).Google Scholar

Copyright information

© Springer Science+Business Media B.V. 2008

Authors and Affiliations

  • L.C. Luo
    • 1
  • B.Q. Qin
    • 1
  1. 1.State Key Laboratory of Lake Science and EnvironmentNanjing Institute of Geography and Limnology, Chinese Academy of SciencesNanjing 210008P. R. China

Personalised recommendations