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DC 欄位 | 值 | 語言 |
---|---|---|
dc.contributor.advisor | 謝志豪(Chih-hao Hsieh) | |
dc.contributor.author | Chen-Yi Tu | en |
dc.contributor.author | 杜貞儀 | zh_TW |
dc.date.accessioned | 2021-06-15T05:07:12Z | - |
dc.date.available | 2013-07-28 | |
dc.date.copyright | 2010-07-28 | |
dc.date.issued | 2010 | |
dc.date.submitted | 2010-07-26 | |
dc.identifier.citation | Alheit J., E. Hagen, in History and Climate. Memories of the Future, P. D. Jones, A. E. J. Ogilvie, T. D. Davies, K. R. Briffa, Eds. (Kluwer/Plenum, New York, 2001), pp. 247-265.
Bainbridge, R. (1958), The speed of swimming of sish as related to size and to the frequency and amplitude of the tail beat, Journal of Experimental Biology, 35, 109-133. Bakun, A., and R. H. Parrish (1991), Comparative studies of coastal pelagic fish reproductive habitats: the anchovy (Engraulis anchoita) of the southwestern Atlantic, ICES Journal of Marine Science, 48, 343-361. Batchelder, H. P., C. A. Edwards, and T. M. Powell (2002), Individual-based models of copepod populations in coastal upwelling regions: implications of physiologically and environmentally influenced diel vertical migration on demographic success and nearshore retention, Progress in Oceanography, 53, 307–334. Capella, J. E., L. B. Quetin, E. E. Hofmann, and R. M. Ross (1992), Models of the early life history of Euphausia superba--Part II. Lagrangian calculations, Deep Sea Research Part A. Oceanographic Research Papers, 39, 1201-1220. Chang, P., and A. Isobe (2005), Interannual variation of freshwater in the Yellow and East China Seas: roles of the Changjiang discharge and wind forcing, Journal of Oceanography, 61, 817-834. Chang, Y., T. Shimada, M. A. Lee, H. J. Lu, F. Sakaida, and H. Kawamura (2006), Wintertime sea surface temperature fronts in the Taiwan Strait, Geophysical Research Letters, 33, L23603. Chen, C. P. Xue, P. Ding, R. C. Beardsley, Q. Xu, X. Mao, G. Gao, J. Qi, C. Li, H. Lin, G. Cowles and M. Shi (2008), Physical mechanisms for the offshore detachment of the Changjiang Diluted Water in the East China Sea, Journal of Geophysical Research, 113, C02002. Chen, C. S., and T. S. Chiu (2003), Early life history traits of Japanese anchovy in the northeastern waters of Taiwan, with reference to larval transport, Zoological Studies, 42, 248-257. Chiu, T. S., and C. S. Chen (2001), Growth and temporal variation of two Japanese anchovy cohorts during their recruitment to the East China Sea, Fisheries Research, 53, 1-15. Chiu, T. S., S. S. Young, and C. S. Chen (1997), Monthly variation of larval anchovy fishery in I-lan bay, NE Taiwan, with an evaluation for optimal fishing season, Journal of the Fisheries Society of Taiwan, 24, 273-282. Cowen, R. K., C. B. Paris, and A. Srinivasan (2006), Scaling of connectivity in marine populations, Science, 311, 522-527. Dietrich, D. E. (1998), Application of a modified Arakawa ‘a’ grid ocean model having reduced numerical dispersion to the Gulf of Mexico circulation, Dynamics of Atmospheres and Oceans, 27, 201-217. Dietrich, D. E., A. Mehra, R. L. Haney, M. J. Bowman, and Y. H. Tseng (2004), Dissipation effects in North Atlantic Ocean modeling, Geophysical Research Letters, 31, L05302. Dietrich, D. E., Y. H. Tseng, R. Medina, S. A. Piacsek, M. Liste, M. Olabarrieta, M. J. Bowman, and A. Mehra, (2008) Mediterranean Overflow Water (MOW) simulation using a coupled multiple-grid Mediterranean Sea/North Atlantic Ocean model, Journal of Geophysical Research, 113, C7. Fujian Fauna and Flora Editing Committee (2003), Fauna and Flora of Fujian Province In Chorography of Fujian Province (in Chinese), 10, 541-542, Fangzhi Press, Beijing, China. Fraenkel, G. S., and D. L. Gunn (1940), The orientation of animals: kineses, taxes and compass reactions, Oxford University Press, Oxford. Franks, P. J. S., J. S. Wroblewski, and G. R. Flierl (1986), Behavior of a simple plankton model with food-level acclimation by herbivores, Marine Biology, 91, 121-129. Gong, G. C., J. Chang, K. P. Chiang, T. M. Hsiung, C. C. Hung, S. W. Duan, and L. A. Codispoti (2006), Reduction of primary production and changing of nutrient ratio in the East China Sea: Effect of the Three Gorges Dam, Geophysical Research Letters, 33, 1–4. Grünbaum, D. (1998), Schooling as a strategy for taxis in a noisy environment, Evolutionary Ecology, 12, 503-522. Guan, B. X. (1994), Patterns and structures of the currents in Bohai, Huanghai and East China Seas. In Oceanology of China Seas, 1, 17–26. ed. By Z. Di et al., Kluwer Acad., Norwell, Mass. Hellerman, S., and M. Rosenstein (1983), Normal monthly wind stress over the world ocean with error estimates, Journal of Physical Oceanography, 13, 1093-1104. Hinch, S. G., and J. Bratty (2000), Effects of swim speed and activity pattern on success of adult sockeye salmon migration through an area of difficult passage, Transactions of the American Fish Society, 129, 598-606. Hinch, S. G., and P. S. Rand (2000), Optimal swimming speeds and forward-assisted propulsion: energy-conserving behaviors of upriver-migrating adult salmon, Canadian Journal of Fisheries and Aquatic Sciences, 57, 2470–2478. Houde, E. D. (1987), Fish early life dynamics and recruitment variability, in American Fisheries Society Symposium, 2, 17–29. Hsia, K.Y., K. T., Lee and M.A, Lee (1998), Fishing ground formation of larval anchovy in relation to oceanography and meteorological conditions in the I-Lan Bay of northeastern Taiwan. Journal of Fishery Society of Taiwan, 25, 239-249 Hsia, K.Y., K. T., Lee, C.H. Liao and J.E. Wang (2004), Effects of changes in sea surface temperature on fluctuation in larval anchovy resources in coastal waters of Taiwan. Journal of Fishery Society of Taiwan, 31, 127-140 Hsieh, C. H., C. S. Chen, T. S. Chiu, K. T. Lee, F. J. Shieh, J. Y. Pan, and M. A. Lee (2009), Time series analyses reveal transient relationships between abundance of larval anchovy and environmental variables in the coastal waters southwest of Taiwan, Fisheries Oceanography, 18, 102-117. Humston R., Ault J.S., Lutcavage M., and Olson D.B. (2000), Schooling and migration of large pelagic fishes relative to environmental cues, Fisheries Oceanography, 9, 136-146. Isobe, A (2008), Recent advances in ocean-circulation research on the Yellow Sea and East China Sea shelves, Journal of Oceanography, 64, 569-584. Iversen, S. A., D. Zhu, A. Johannessen, and R. Toresen (1993), Stock size, distribution and biology of anchovy in the Yellow Sea and East China Sea, Fisheries Research, 16, 147-163. Jan, S., D. D. Sheu, and H. M. Kuo (2006), Water mass and throughflow transport variability in the Taiwan Strait, Journal of Geophysics Research, 111, 1-15. Jan, S., J. Wang, C. S. Chern, and S. Y. Chao (2002), Seasonal variation of the circulation in the Taiwan Strait, Journal of Marine Systems, 35, 249-268. Jan, S., Y. Tseng, and D. Dietrich (2010), Sources of water in the Taiwan Strait, Journal of Oceanography, 66, 211-221. Johnson, C., J. Pringle, and C. Chen (2006), Transport and retention of dormant copepods in the Gulf of Maine, Deep Sea Research Part II: Topical Studies in Oceanography, 53, 2520-2536. Lee, H. J., S. Y. Chao, and K. K. Liu (2004), Effects of Reduced Yangtze River Discharge on the Circulation of Surrounding Seas, TAO: Terrestrial, Atmospheric and Oceanic Sciences, 15, 111-132. Lee, H., and S. Chao (2003), A climatological description of circulation in and around the East China Sea, Deep Sea Research Part II: Topical Studies in Oceanography, 50, 1065-1084. Lee, H., and S. Chao (2003), A climatological description of circulation in and around the East China Sea, Deep Sea Research Part II: Topical Studies in Oceanography, 50, 1065-1084. Lee, M.A, K. T., Lee and G. Y. Shiah (1995), Environmental factors associated with the formation of larval anchovy fishing grounds in the coastal waters of southwest Taiwan. Marine Biology, 121, 621-625 Lee, T. N., W. E. Johns, C. Liu, D. Zhang, R. Zantopp, and Y. Yang (2001), Mean transport and seasonal cycle of the Kuroshio east of Taiwan with comparison to the Florida Current, Journal of Geophysical Research, 106, 22143-22158. Leggett, W. C., and E. Deblois (1994), Recruitment in marine fishes: Is it regulated by starvation and predation in the egg and larval stages?, Netherlands Journal of Sea Research, 32, 119-134. Levitus, S., and T. P. Boyer (1994), World ocean atlas 1994, volume 4: Temperature, PB–95-270112/XAB, National Environmental Satellite, Data, and Information Service, Washington, DC. Liang, W. D., T. Y. Tang, Y. J. Yang, M. T. Ko, and W. S. Chuang (2003), Upper-ocean currents around Taiwan, Deep Sea Research Part II: Topical Studies in Oceanography, 50, 1085-1105. Liao, J. C. (2007), A review of fish swimming mechanics and behavior in altered flows, Philosophical Transactions B, 362, 1973-1993. Lin, S., T. Tang, S. Jan, and C. Chen (2005), Taiwan strait current in winter, Continental Shelf Research, 25, 1023-1042. Ljung, L (1999), System Identification: Theory for the User, 2nd ed., Prentice Hall. Lloret, J., I. Palomera, J. Salat, and I. Sole (2004), Impact of freshwater input and wind on landings of anchovy (Engraulis encrasicolus) and sardine (Sardina pilchardus) in shelf waters surrounding the Ebre (Ebro) River delta (north-western Mediterranean), Fisheries Oceanography, 13, 102–110. North, E. W., Z. Schlag, R. R. Hood, M. Li, L. Zhong, T. Gross, and V. S. Kennedy (2008), Vertical swimming behavior influences the dispersal of simulated oyster larvae in a coupled particle-tracking and hydrodynamic model of Chesapeake Bay, Marine Ecology Progress Series, 359, 115. Parrish, J. K., and S. V. Viscido (2002), Self-Organized Fish Schools: An Examination of Emergent Properties, Biological Bulletin, 202, 296–305. Pedersen, O. P., K. S. Tande, and D. Slagstad (2001), A model study of demography and spatial distribution of Calanus finmarchicus at the Norwegian coast, Deep Sea Research Part II: Topical Studies in Oceanography, 48, 567-587. Rothschild, B. J., and M. J. Fogarty (1989), Spawning-stock biomass: A source of error in recruitment/stock relationships and management advice, ICES Journal of Marine Science, 45, 131-135. Runge, J. A., P. J. Franks, W. C. Gentleman, B. A. Megrey, K. A. Rose, F. E. Werner, and B. Zakardjian (2004), Diagnosis and prediction of variability in secondary production and fish recruitment processes: developments in physical–biological modeling, The Sea, 13, 353–374. Schöne, H. (1984), Spatial Orientation: Spatial Control of Behavior in Animals and Man. Princeton, NJ: Princeton University Press. Sfakiotakis, M., D. M. Lane, and J. B. C. Davies (1999), Review of Fish Swimming Modes for Aquatic Locomotion, IEEE Journal of Oceanic Engineering, 24, 237. Shiah, F. K., G. C. Gong, and T. Xiao (2006), Effects of ChangJiang River summer discharge on bottom-up control of coastal bacterial growth, Aquatic Microbial Ecology, 44, 105. Takasuka, A., Y. Oozeki, H. Kubota, Y. Tsuruta, and T. Funamoto (2005), Temperature impacts on reproductive parameters for Japanese anchovy: Comparison between inshore and offshore waters, Fisheries Research, 76, 475-482. Tang, T. Y., J. H. Tai, and Y. J. Yang (2000), The flow pattern north of Taiwan and the migration of the Kuroshio, Continental Shelf Research, 20, 349-371,. Tsai, C., P. Chen, C. Chen, M. A. Lee, G. Y. Shiah, and K. Lee (1997), Fluctuation in abundance of larval anchovy and environmental conditions in coastal waters off south-western Taiwan as associated with the El Nino-Southern Oscillation, Fisheries Oceanography, 6, 238-249. Tzeng, W., and Y. Wang (1993), Hydrography and distribution dynamics of larval and juvenile fishes in the coastal waters of the Tanshui River estuary, Taiwan, with reference to estuarine larval transport, Marine Biology, 116, 205-217. Viscido, S. V., J. K. Parrish, and D. Grünbaum (2004), Individual behavior and emergent properties of fish schools: a comparison of observation and theory, Marine Ecology Progress Series, 273, 239–249. Wardle, C., J. Videler, and J. Altringham (1995), Tuning in to fish swimming waves: body form, swimming mode and muscle function, Journal of Experimental Biology, 198, 1629-1636. Weihs, D. (1973), Optimal Fish Cruising Speed, Nature, 245, 48-50. Werner, F. E., R. Ian Perry, R. Gregory Lough, and C. E. Naimie (1996), Trophodynamic and advective influences on Georges Bank larval cod and haddock, Deep Sea Research Part II: Topical Studies in Oceanography, 43, 1793-1822. Whitehead, P. J., G. J. Nelson, and T. Wongratana (1988), Clupeoid fishes of the world (suborder Clupeoidei): an annotated and illustrated catalogue of the herrings, sardines, pilchards, sprats, shads, anchovies, and wolfherrings, Food & Agriculture Org. Young, S. S. (1994), Fishery Biology of Japanese Anchovy (Engraulis japonica T. and S.) in I-lan Bay. Ph.D thesis, Institute of Zoology, National Taiwan University. Young, S. S., C. C. Chen, and T. S. Chiu (1992), Resource characteristics of young herring-like fish in the I-Lan Bay area-fishing season, major species and size variation, J. Fish. Soc. Taiwan, 19, 273–281. Yu, H. T., Y. J. Lee, S. W. Huang, and T. S. Chiu (2002), Genetic Analysis of the Populations of Japanese Anchovy (Engraulidae: Engraulis japonicus) Using Microsatellite DNA, Marine Biotechnology, 4, 471-479. Yu, Z., X. Kong, C. S. Chen, Y. Jiang, Z. Zhuang, and X. Jin (2005), Mitochondrial DNA sequence variation of Japanese anchovy Engraulis japonicus from the Yellow Sea and East China Sea, Fisheries Science, 71, 299-307. Zhang, J. (1996), Nutrient elements in large Chinese estuaries, Continental Shelf Research, 16, 1023-1045. | |
dc.identifier.uri | http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/46401 | - |
dc.description.abstract | 日本鯷的仔稚魚(吻仔魚)為台灣重要的經濟漁業物種,自1990年代以來捕獲量開始明顯減少。一般認為產卵成魚數量會直接影響其再添加過程,進而影響其漁獲量。然而,日本鯷屬於多次產卵、且有多個產卵場的物種,因此在野外進行產卵場與產卵洄游研究十分困難。故本研究中使用魚類行為-物理洋流耦合模式(Coupled fish behavior-hydrodynamic model)進行日本鯷產卵洄游模擬,試圖了解在洄游過程中環境對產卵洄游的影響。
本模式中的環境部份使用DUPOM(Dual-grid Pacific Ocean Model)海洋環流模式進行模擬。此模式以DieCAST環流模式為基礎,並在模擬中加入長江淡水輸入,以了解三峽大壩完工後,長江流量減少對周遭海域的影響。生物部份使用拉氏顆粒追蹤模式(Lagrangian particle traciking program)模擬日本鯷洄游,並加入初階魚類游泳行為以探討游泳在洄游過程中所扮演的角色。 結果發現,中國沿岸流(China Coastal Current)的強度受長江流量的多寡所影響,對日本鯷產卵洄游有很大的助益。此外,游泳行為也十分關鍵,將會影響洄游方向與抵達時間,使日本鯷能在產卵季開始前抵達近岸的產卵場。本研究也顯示,使用物理洋流模式與簡化生物模式耦合,可以更加了解海洋中環境因子與生物過程將如何影響其中的魚類族群。 | zh_TW |
dc.description.abstract | The Japanese anchovy (Engraulis japonicus) larval fishery is one of the important fisheries in Taiwan, and the fishery catch has significantly decreased since the 1990s. The abundance of spawning adults likely influences the recruitment process and thus the fishery catches. However, Japanese anchovy is known as a multi-batch species with many different spawning grounds, which makes the field study of the onset of spawning migration and its possible migration routes difficult.
Here, an approach based on a coupled fish behavior-hydrodynamic model is used to simulate spawning migration of Japanese anchovy. The physical part consists of an ocean circulation model - Dual-grid Pacific Ocean Model (DUPOM), which is based on the fourth-order accurate, collocated Arakawa-A grid DieCAST (Dietrich/Center for Air Sea Technology) model. The change of Changjiang discharge is also included for investigating the potential influence of reduction in discharge causing by Three Gorge Dam. The biological part uses the Lagrangian particle tracking program to simulating fish migration with a primarily approximation of fish swimming behavior. The simulation results suggest that the spawning migration of Japanese anchovy may be aided by the China Coastal Current (CCC). In addition, the Changjiang discharge has significant influence on the migration of Japanese anchovy. The swimming behavior of anchovies is crucial during spawning migration, as it provides extra velocity for fish moving farther and closer to the coastal area. Results in this research demonstrate that a physical model coupled with a simplified biological model can help us better understand how the biological processes and marine environment affecting the fish population. | en |
dc.description.provenance | Made available in DSpace on 2021-06-15T05:07:12Z (GMT). No. of bitstreams: 1 ntu-99-R97241213-1.pdf: 2629693 bytes, checksum: 5d6103dd2b21d93afaaa2e4652c02643 (MD5) Previous issue date: 2010 | en |
dc.description.tableofcontents | Table of Contents
Introduction 1 1. Japanese anchovy and the larval fishery 1 2. Physical-biological coupled model 3 3. Circulation in East China Sea 4 4. Objective 6 Material and method 7 1. Fishery data analysis 7 2. Model description 7 Physical environment 7 Lagrangian particle tracking simulation 9 The Fish behavior model 9 Result 12 1. Physical environment 12 2. Fish migration simulation 13 Experiment 0: Passive 13 Experiment 1: Swimming along with current 14 Experiment 2: Stepwise- swimming along current until sensing optimum spawning temperature (22˚C) 15 Discussion 16 Model validation: comparing the simulation result with fishery records 16 Influence of Changjiang discharge on the East China Sea 16 Swimming behavior modeling of fish 17 Challenge in hydrodynamic modeling 20 Conclusion 21 Reference 22 Table of Figures Table 1. Simulation scenarios. 29 Figure 1. Japanese anchovy (Engraulis japonicus) adult 30 Figure 2. Hypothetical spawning migration routes of Japanese anchovy from the East China Sea to Taiwan coast. 31 Figure 3. Monthly and seasonality of catch per unit effort of Japanese anchovy 32 Figure 4. Model domain and resolution of DUPOM 33 Figure 5. Monthly Changjiang river discharge 34 Figure 7. Schematic diagram of temperature perception zone in the fish behavior model 36 Figure 8. Monthly mean sea surface temperature in control and standard run 37 Figure 9. Distribution of monthly mean near-surface current velocity 38 Figure 10. Monthly average near-surface salinity in standard run 39 Figure 11. Tracer trajectories of Experiment 0 in control and standard run. 40 Figure 12. Tracer trajectories of Experiment 1 in control and standard run. 41 Figure 13. Tracer trajectories of Experiment 2 in control and standard run. 42 Figure 14. Modified spawning migration routes 43 | |
dc.language.iso | en | |
dc.title | 利用魚類行為-物理洋流耦合模式探討日本鯷於東海至台灣之產卵洄游途徑 | zh_TW |
dc.title | Using coupled fish behavior-hydrodynamic model to investigate spawning migration of Japanese anchovy, Engraulis japonicus, from the East China Sea to Taiwan | en |
dc.type | Thesis | |
dc.date.schoolyear | 98-2 | |
dc.description.degree | 碩士 | |
dc.contributor.coadvisor | 曾于恒(Yu-Heng Tseng) | |
dc.contributor.oralexamcommittee | 丘臺生(Tai-Sheng Chiu),詹森(Sen Jan) | |
dc.subject.keyword | 長江,漁業再添加過程,魚類游泳行為模式,日本鯷,物理-生物相互作用, | zh_TW |
dc.subject.keyword | Changjiang,fishery recruitment process,fish swimming behavior model,Japanese anchovy,Physical-biological coupling, | en |
dc.relation.page | 43 | |
dc.rights.note | 有償授權 | |
dc.date.accepted | 2010-07-27 | |
dc.contributor.author-college | 理學院 | zh_TW |
dc.contributor.author-dept | 海洋研究所 | zh_TW |
顯示於系所單位: | 海洋研究所 |
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