臺灣海峽北部撓腳類與仔稚魚群集組成受水文因數之影響

謝志豪

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DC 欄位	值	語言
dc.contributor.author	謝志豪	zh_TW
dc.date.accessioned	2021-07-01T08:12:16Z	-
dc.date.available	2021-07-01T08:12:16Z	-
dc.date.issued	2001
dc.identifier.citation	Azam, F, Fenchel JT, Field JG, Gray JS, Meyer-Reil LA, Thingstad F (1983) The ecological role of water-column microbes in the sea. Mar Ecol Prog Ser 10: 257-263. Boucher M (1984) Localization of zooplankton populations in the Ligurian marine front: role of ontogenetic migration. Deep-Sea Res 29: 953-965. Boucher M, Ibanez F, Prieur L (1987) Daily and seasonal variations in the spatial distribution of zooplankton populations in relation to the physical structure in the Ligurian Sea Front. J Mar Res 45: 133-173. Bradford-Grieve JM (1994) Pelagic calanoid Copepoda: Megacalanidae, Calanidae, Paracalanidae, Mecynoceridae, Eucalanidae, Spinocalanidae, Clausocalanidae. New Zealand Oceanographic Institute Memoir 102: 1-160. Brian M, St. John M, Wieland K (1996) Eastern Baltic cod: perspectives from existing data on processes affecting growth and survival of eggs and larvae. Mar Ecol Prog Ser 134: 265-281. Chen CS, Chiu TS (1992) Comparison of ichthyoplankton guild in the Kuroshio edge exchange area. Terrestr Atmos Oceanic Sci 3: 335-346. Chen HY, Chen YLL (1992) Quantity and quality of summer surface net zooplankton in the Kuroshio current-induced upwelling northeast of Taiwan. Terrestr Atmos Oceanic Sci 3: 321-334. Chen QC (1992) Zooplankton of China Seas (1). Science Press, Beijing, pp. 1-87. Chen QC, Zhang SZ (1965) The planktonic copepods of the Yellow Sea and the East China Sea. 1. Calanoida (In Chinese). Stud Mar Sin 7: 20-133. Chen QC, Zhang SZ, Zhu CS (1974) On planktonic copepods of the Yellow Sea and the East China Sea. 2. Cyclopoida and Harpacticoida (In Chinese). Stud Mar Sin 9: 27-100. Chen YLL (1995) Phytoplankton composition and productivity in response to the upwelling of northeastern Taiwan. Proc Natl Sci Counc, ROC 19B (1): 66-72. Cheng CC (1998) The distribution correlation between planktonic copepods and ichthyoplankton in the western North Pacific (In Chinese with English abstract). M. Sc. Thesis, National Taiwan University. Chern CS, Wang J (1989) On the water masses at northern offshore area of Taiwan. Acta Oceanogr Taiwan 22: 14-32. Chern CS, Wang J, Wang DP (1990) The exchange of Kuroshio and East China Sea shelf water. J Geophys Res 95: 16017-16023. Chiang KP, Shiah FK, Gong GC (1997) Distribution of summer diatom assemblages in and around a local upwelling in the East China Sea northeast of Taiwan. Botanic Bull Acad Sin 38: 121-129. Chiu TS (1991) Variation of ichthyoplankton density across the Kuroshio edge exchange area with implication to the water masses. Terrestr Atmos Oceanic Sci 2: 147-262. Chiu TS (1992) An exploration on ichthyoplankton assemblage in the water off southwestern Taiwan, with an inference on the role of Kuroshio on the distribution of ichthyoplankton. J Fish Soc Taiwan 19(1): 1-12. Chiu TS, Chang KZ (1994) Comparison of ichthyoplankton fauna in northern Taiwan Strait during winter and spring. Acta Zool Taiwan 5: 23-31. Chiu TS, Chang KZ (1995) Diurnal cycling in vertical distribution of ichthyoplankton at a fixed station off northwestern Taiwan. Zool Stud 34: 183-192. Chiu TS, Chen CS (1997) Distribution of ichthyoplankton in the waters off southwestern Taiwan. Proc Nat Sci Coun (ROC) 21(2): 79-89. Chiu TS, Hsyu YH (1994) Interannual variation of ichthyoplankton density and species composition in the waters off northern Taiwan. Mar Biol 119: 441-448. Chiu TS, Lee PY (1991) Initial ichthyoplankton studies in the Kuroshio edge exchange area. Bull Inst Zool Acad Sin 30: 261-272. Collins NR, Williams R (1981) Zooplankton of the Bristol Channel and Severn estuary. The distribution of four copepods in relation to salinity. Mar Biol 64: 273-283. Cushing DH (1975) Marine Ecology and Fisheries. Cambridge University Press, Oxford, pp. 1-278. Dufrene M, Legendre P (1997) Species assemblages and indicator species: the need for a flexible asymmetrical approach. Ecol Monogr 67: 345-366. Fager EW (1957) Determination and analysis of recurrent groups. Ecol 38: 586-595. Fang KL (1982) A study of water masses in Taiwan Strait. Acta Oceanogr Taiwan 13: 140-153. Fang KL, Yu CY (1981) A study of water masses in the seas of southernmost Taiwan. Acta Oceanogr Taiwan 12: 94-111. Fernandez E, Cabal J, Acuna JL, Bode A, Botas A, Garcia-Soto C (1993) Plankton distribution across a slope current-induced front in the southern Bay of Biscay. J Plankton Res 15: 619-641. Frank KT, Leggett WC (1982) Environmental regulation of growth rate, efficiency and swimming performance in larval capelin (Mallotus villosus), and its application to the match/mismatch hypothesis. Can J Fish Aquat Sci 39: 691-699. Frost B, Fleminger A (1968) A revision of the genus Clausocalanus (Copepoda: Calanoida) with remarks on distributional patterns in diagnostic characters. Bull Scripps Institution of Oceanography, University of California, San Diego. 12: 1-235. Gauch Jr HG (1983) Multivariate Analysis in Community Ecology. Cambridge University Press, New York, pp. 1-298. GLOBEC Focus 1 Working Group Report. Retrospective Analyses and Time Series Studies. Report of the first Meeting, Sitges, Spain, 18-19 May 2000. GLOBEC Focus 2 Working Group Report. Process Studies. Report No 1 of the first Meeting, Roscoff, France, 10-13 September 2000. GLOBEC Focus 3 Working Group Report. Modelling and Predictive Capabilities. GLOBEC Focus 3 Working Group Chapel Hill 2000 Meeting Report. University of North Carolina, Chapel Hill, USA, 9-12 July 2000. Gowen RJ, Raine R, Dickey-Collas, White M (1998) Plankton distributions in relation to physical oceanographic features on the southern Malin Shelf, August 1996. ICES J Mar Sci 55: 1095-1111. Hansen FC, Reckermann M, Klein Breteler WCM, Riegman R (1993) Phaeocystis blooming enhanced by copepod predation on protozoa: evidence from incubation experiments. Mar Ecol Prog Ser 102: 51-57. Harris, R. (2000) News of the GLOBEC focus working groups. GLOBEC International Newsletter 6.1: 20-22. Haury LR, Pieper RE (1988) Zooplankton: scales of biological and physical events. In: Soule DF, Kleppel GS (eds). Marine Organisms as Indictors. Springer-Verlag, Inc., New York, pp. 35-72. Hill MO, Bunce RGH, Shaw MW (1975) Indicator species analysis, a divisive polythetic method of classification, and its application to a survey of native pinewoods in Scotland. J Ecol 63: 597-613. Hirakawa K, Goto T, Hirai M (197) Diet composition and prey size of larval anchovy, Engraulis japonicus, in Toyama Bay, southern Japan Sea. Bull Japan Natl Fish Res Inst 7: 67-78. Hirakawa K, Oawa Y (1996) Characteristics of the copepod assemblage in the southwestern Japan Sea and its implication for anchovy population dynamics. Bull Japan Natl Fish Res Inst 46: 45-64. Hjort J (1914) Fluctuations in the great fisheries of northern Europe viewed in the light of biological research. Rapp P-v reun Cons Perm Int Explor Mer 20:1-228. Hofmann EE, Lascara CM (1998) Chapter 19. Overview of interdisciplinary modeling for marine ecosystem. In: Brink KH, Robinson AR (eds). The Sea. Vol. 10. John Wiley and Sons, Inc., New York, pp. 507-540. Hollander M, Wolfe DA (1999) Nonparametric Statistical Methods. 2ed. John Wiley and Sons, Inc., New York, pp. 1-787. Hsieh CH, Chiu TS (1998) Copepod abundance and species composition of Tanshui River estuary and adjacent waters. Acta Zool. Taiwanica. 9: 1-9. Huang BQ, Hong HS, Wang HL (1999) Size-fractionated primary productivity and the phytoplankton-bacteria relationship in the Taiwan Strait. Mar Ecol Prog Ser 183: 29-38. Huang JB, Chiu TS (1998) Seasonal and hydrographic variations of ichthyoplankton density and composition in the Kuroshio edge exchange area off northeastern Taiwan. Zool Stud 37: 63-73. Huang R (1986) Phytoplankton distribution off the southwestern coast of Taiwan. Acta Oceanogr Taiwan 16: 103-116. Huang R (1988) The influence of hydrography on the distribution of phytoplankton in the southern Taiwan Strait. Estuar Coast Shelf Sci 26: 643-656. Huang R, Huang CC (1987) Plankton communities in the surface waters of Taiwan Strait. Acta Oceanogr Taiwan 18: 16-23. Huys R, Boxshall GA (1991) Copepod Evolution. The Ray Society, London, 159: 1-448. Iles TD, Sinclair M (1982) Atlantic herring: stock discreteness and abundance. Science 215:627-633. Jan S (1995) Seasonal variations of currents in the Taiwan Strait (In Chinese with English abstract). Ph.D. Thesis. National Taiwan University. Jan S, Chern CS, Wang J (1994) Influences of sea surface wind stress on summertime flow pattern in the Taiwan Strait (In Chinese with English abstract). Acta Oceanogr Taiwan 33: 63-80. Jan S, Chern CS, Wang J (1995) A numerical study on currents in Taiwan Strait during summer time. La mer 33: 23-40. Jan S, Chern CS, Wang J (1998) A numerical study of currents in the Taiwan Strait during winter. Terrestr Atmos Oceanic Sci 9: 615-642. Kim S (2000) GLOBEC activities in Korea waters. GLOBEC Report. Krebs CJ (1989) Ecological Methodology. Harper & Row Publishers, New York, pp. 1-654. Lalli CM, Parson TR (1993) Biological Oceanography: an Introduction. Pergamon Press, Oxford, pp. 1-301. Lasker R (1975) Field criteria for survival of anchovy larvae: the relation between inshore chlorophyll maximum layer and successful first feeding. U S Nat Mar Fish Ser Fish Bull 73: 453-462. Lasker R (1981) The role of a stable ocean in larval fish survival and subsequent recruitment. In: Lasker R (ed.) Marine Fish Larvae: Morphology, Ecology and relation to fisheries. Washington Sea Grant Program, Seattle, WA, pp. 80-87. Lian GS, Lin JM (1983) On the taxonomy of the pelagic copepods in the south Yellow Sea and the East China Sea. (In Chinese). Collected Oceanic Works 6: 127-148. Liu KK, Gong GC, Lin SW, Yang CY, Wei CL, Pai SC, Wu CK (1992a) The year-round upwelling at the shelf break near the northern tip of Taiwan as evidenced by chemical hydrography. Terrestr Atmos Oceanic Sci 3: 243-276. Liu KK, Gong GC, Pai CZ, Wei CL, Chao SY (1992b) Response of Kuroshio upwelling to the onset of the northeast monsoon in the sea north of Taiwan: observations and a numerical simulation. J Geophys Res 97: 12511-12526. Luan WC, Chen ST, Yang L, Chang LP, Jang LC, Chang F, Wu LY, Kao SH (1988) Distribution of dissolved oxygen. In Fujian Institute of Oceanography (eds.) A Comprehensive Oceanographic Survey of the Central and Northern Part of Taiwan Strait (In Chinese). Science Press, Beijing, pp. 209-224. Mallin MA (1991) Zooplankton abundance and community structure in a mesohaline North Carolina estuary. Estuaries 14: 481-488. Maravelias CD, Reid D G (1997) Identifying the effect of oceanographic features and zooplankton on prespawning herring abundance using generalized additive models. Mar Ecol Prog Ser 147: 1-9. Markhaseva EL (1996) Calanoid copepods of the family Aetideidae of the world ocean. Trudy Zool Inst RAN 268: 1-331. May RC (1974) Larval mortality in marine fishes and the critical period concept. In: Blaxter JHS (ed.), The Early Life History of Fishes. Springer-Verlag, Berlin, pp. 3-19. McCune B, Mefford MJ (1997) Multivariate Analysis of Ecological Data. MjM Software, Gleneden Beach, Oregon, U.S.A. Metz C, Schnack-Schiel SB (1995) Observations on carnivorous feeding in Antarctic calanoid copepods. Mar Ecol Prog Ser 129: 71-75. Nishida S (1985) Taxonomy and distribution of the Famiy Oithonidae (Copepoda: Cyclopoida) in the Pacific and Indian oceans. Bull Ocean Research Institute, University of Tokyo. 20: 1-167. Noda M, Ikeda I, Ueno S, Hashimoto H, Gushima K (1998) Enrichment of coastal zooplankton communities by drifting zooplankton patches from Kuroshio front. Mar Ecol Prog Ser 170: 55-65. Okiyama M (1988) An Atlas of the Early stages fishes in Japan (in Japanese). Takai University Press, Japan, pp1-1154. Oozeki Y (2000) Mechanism causing the variability of the Japanese sardine population: Achievements of the Bio-Cosmos Project in Japan. GLOBEC Report. Park T (1995) Taxonomy and distribution of the marine calanoid copepod family Euchaetidae. Bull Scripps Institution of Oceanography, University of California, San Diego. 29: 1-203. Pielou EC (1984) The Interpretation of Ecological Data. John Wiley & Sons Press, New York, pp. 1-263. Poulet SA, Williams R (1991) Characteristics and properties of copepods affecting the recruitment of fish larvae. Bull Plankton Soc Japan Spec Vol.: 271-290. Roman MR, Gauzens AL, Rhinehart WK, White JR (1993) Effects of low oxygen waters on Cheasepeak Bay zooplankton. Limnol Oceanogr 38: 1603-1614. Runge JA (1988) Should we expect a relationship between primary production and fisheries The role of copepod dynamics as a filter of trophic variability. Hydrobiol 167/168: 61-71. Shiah FK, Gong GC, Liu KK (1995) A preliminary survey on primary productivity measured by the 14C assimilation method in the KEEP area. Acta Oceanogr Taiwan 34: 1-15. Shih C-t, Chiu TS (1998) Copepod diversity in the water masses of the southern East China Sea north of Taiwan. J Mar Sys 15: 533-542. Sinclair M, Tremblay MJ (1984) Timing of spawning of Atlantic herring (Clupea harengus harengus) population and the match-mismatch theory. Can J Fish Aquat Sci 41: 1055-1065. Soul DF (1988) Marine organisms as indicators: reality or wishful thinking In: Soule DF, Kleppel GS (eds). Marine Organisms as Indictors. Springer-Verlag, Inc., New York, pp. 1-12. Steele JH (1998) From carbon flux to regime shift. Fish Oceanogr 7: 176-181. Tan TH (1967) On the distribution of copepods in waters surrounding Taiwan. Rep Inst Fisher Biol, Ministry of Economic Affairs and National Taiwan University 2(2): 14-20. Tang QS (2000) The new age of China-GLOBEC study. GLOBEC Report. Tang TY, Hseuh Y, Yang YJ, Ma JC (1999) Continental slope flow northeast Taiwan. J Phys Oceanogr 29: 1353-1362. ter Braak CJF (1994) Canonical community ordination. Part I: Basic theory and linear method. Ecosci 1: 127-140. Thomas AC, Emery WJ (1986) Winter hydrography and plankton distribution on the southern British Columbia continental shelf. Can J Fish Aquat Sci 43: 1249-1258. Townsend DW (1992) Ecology of larval herring in relation to the oceanography of the Gulf of Maine. J Plankton Res 14: 467-493. Tremblay MJ, Roff JC (1983) Community gradients in the Scotia shelf zooplankton. Can J Fish Aquat Sci 40: 598-611. Tzeng WN, Wang YT (1992) Structure, composition and seasonal dynamics of the larval and juvenile fish community in the mangrove estuary of Tanshui River, Taiwan. Mar Biol 113: 481-490. Tzeng WN, Wang YT (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. Mar Biol 116: 205-217. Wang HL, Huang BQ, Hong HS (1997) Size-fractionated productivity and nutrient dynamics of phytoplankton in subtropical coastal environments. Hydrobiol 352: 97-106. Werner FE, Perry RI, Lough G, Naimie CE (1996) Trophodynamic and advective influences on Georges Bank larval cod and haddock. Deep-sea Res II 43: 1793-1822. Wessel P, Smith WHF (1995) The Generic Mapping Tools (GMT) version 3.0. Technicacal Reference and Cookbook, SOEST/NOAA. Willams R, Conway DVP, Hunt HG (1994) The role of copepods in the planktonic ecosystems of mixed and stratified waters of the European shelf seas. Hydrobiol 292/293: 521-230. Xiao H (1988) Studies of coastal upwelling in western Taiwan Strait. (In Chinese with English abstract). J Oceanogr Taiwan Strait 7: 135-142. Yang L, Chang F, Wu LY, Kao SH, Luan WC, Chen ST, Jang LC, Chang LP (1988) Distribution of chlorophyll a and estimation of primary productivity. In Fujian Institute of Oceanography (eds.) A Comprehensive Oceanographic Survey of the Central and Northern Part of Taiwan Strait (In Chinese). Science Press, Beijing, pp.244-259. Zheng Z, Li SJ, Li S, Chen BY (1982) On the distribution of planktonic copepods in Taiwan strait (In Chinese with English abstract). Taiwan Strait 1: 69-79. Zhu CS, Wu JZ, Lin YS, Su M, Huang CJ, Hu QB (1988) The species composition, distribution and abundance of plankton. In Fujian Institute of Oceanography (eds.) A Comprehensive Oceanographic Survey of the Central and Northern Part of Taiwan Strait (In Chinese). Science Press, Beijing, pp.259-305.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/75222	-
dc.description.abstract	本研究之目的為探討北部臺灣海峽中橈腳類和仔稚魚的物種組成、豐度和分佈對應於水文環境的時空變動。臺灣海峽的水文環境主要受到中國沿岸流、南海表層水以及黑潮支流在不同季節間相互推移，加上地形效應以及源自大陸和台灣的河流沖淡水所調控。從水文資料的分析中我們看到了季節性以及空間性的變異，定義了8個水團，包括夏季：海峽西側水、海峽東側水、東海水；冬季：海峽西側水、海峽東側水、東海水；春季：大陸沿岸水和黑潮水。以橈腳類的物種組成進行對應分析的結果，測站間的社群區分大體上與水文分析中定義的水團一致。以降趨對應分析和K均值分析也得到類似的結果。以仔稚魚物種組成進行對應分析的結果與水團對應不明顯。以降趨對應分析得到的社群區分可以看到季節變異但沒有明顯的空間變異，而K均值分析也得到類似的結果。優勢物種分析也顯示了時空上的變化。我們以典型對應分析探討這些優勢物種與水文因數的關係。再現群分析顯示一個主要群由橈腳類組成，包括了Acrocalanus gibber、Canthocalanus pauper、Euterpina acutifrons、Oithona attenuata、Oithona plumifera、Oncaea conifera、Oncaea venusta、Paracalanus pavus、Parvocalanus crossirostris、Temora turbinata，有兩個仔稚魚物種Benthosema pterotum、Trichiurus lepturus會與橈腳類構成次群，也表示了橈腳類與仔稚魚之間的關係。由物種豐度以及歧異度的分佈情形可以看出，在夏、冬季節有從大陸沿岸往大洋方向遞增的趨勢；春季時，受黑潮影響的區域高於受大陸沿岸水影響的區域。指標種分析顯示了季節性的變化。生物豐度也有季節性變化，以橈腳類而言，夏季＞春季＞冬季；以仔稚魚而言，夏季＞冬季，但夏季與春季無顯著差異，春季與冬季無顯著差異。迴歸分析仔稚魚密度與橈腳類密度成正相關。	zh_TW
dc.description.abstract	This study analyzed the spatial and temporal variation of copepods and larval fishes in relation to the hydrographic conditions of northern Taiwan Strait. The hydrographic conditions are influenced by three main currents, China coastal current, South China Sea warm current and Kuroshio branch current, as well as the topographic effect in the Strait. The river runoffs from the China mainland and Taiwan island also have immense impact. According to the hydrographic data, we defined 8 ecological zones showing seasonal and spatial variations, including summer: western Taiwan Strait, eastern Taiwan Strait, East China Sea; winter: western Taiwan Strait, eastern Taiwan Strait, East China Sea; spring: China coastal current region and Kuroshio branch region. Correspondence analysis based on copepod composition resulted in station associations, which are generally consistent with these ecological zonations. Detrend correspondence analysis and K-means classification also show the similar results. The result of correspondence analysis based on larval fish composition shows no clear zonations. Detrend correspondence analysis resulted in station associations, which shows clear seasonal variation but not spatial zonations, and the result of K-means classification was similar to that of detrend correspondence analysis. Dominant species analysis also validated the seasonal and spatial variations of copepods and larval fishes. Species associations of dominant species of copepods and larval fishes, and the relationship between these species and hydrographic factors were constructed through canonical correspondence analysis. Two-way indicator species analysis provided insightful information concerning the spatial and temporal distribution of dominant species. Recurrent group analysis showed a main concurrent group consisted of copepod species and the relationship between copepod and larval fish species. Analysis on the species richness and diversity revealed that these indices increase from the China costal side to the offshore side in summer and winter and are higher in the area affected by Kuroshio than that affected by China coastal current in spring. Indicator species of copepods and larval fishes of each season were extracted through indicator species analysis. Abundance of copepods and larval fishes also showed seasonal variation. Of copepods, abundance is lower in spring than summer, and least in winter. Of larval fishes, abundance is higher in summer than winter, but no difference exists between summer and spring and between spring and winter. The larval fish abundance is positively related with copepod abundance.	en
dc.description.provenance	Made available in DSpace on 2021-07-01T08:12:16Z (GMT). No. of bitstreams: 0 Previous issue date: 2001	en
dc.description.tableofcontents	謝辭………………………………………………………………i 目錄………………………………………………………………ii 英文摘要…………………………………………………………v 中文摘要…………………………………………………………vii 壹、前言…………………………………………………………1 1．研究地點的地形與水文………………………………………1 1．1．臺灣海峽…………………………………………………1 1．1．1．地形……………………………………………………1 1．1．2．水文……………………………………………………1 1．2．臺灣北部海域……………………………………………3 2．生物與環境……………………………………………………3 2．1．橈腳類……………………………………………………3 2．2．仔稚魚……………………………………………………4 2．3．環境因數…………………………………………………4 2．4．魚類的添加………………………………………………5 3．相關研究………………………………………………………7 3．1．全球海洋生態系統動態研究……………………………7 3．2．臺灣海峽的相關研究……………………………………9 3．3．臺灣北部海域的相關研究………………………………11 4．研究目的………………………………………………………11 貳、材料與方法…………………………………………………13 1．採樣及資料形成………………………………………………13 1．1．野外工作…………………………………………………13 1．2．實驗室工作………………………………………………14 2．資料分析………………………………………………………14 2．1．水文資料…………………………………………………14 2．2．生物資料…………………………………………………15 2．2．1．物種歧異度分析………………………………………15 2．2．2．物種時空分佈…………………………………………15 2．2．3．物種季節變化…………………………………………18 2．3．橈腳類與仔稚魚的食階關係……………………………19 3．衛星資料………………………………………………………19 參、結果…………………………………………………………21 1．水文分析………………………………………………………21 2．物種組成與時空分佈…………………………………………24 2．1．物種與歧異度……………………………………………24 2．2．物種組成的時空變異……………………………………25 2．3．優勢物種與水文因數的關係……………………………26 2．4．橈腳類與仔稚魚的共現性………………………………29 3．季節變化………………………………………………………30 3．1．指標物種分析……………………………………………29 3．2．生物豐度的季節變異……………………………………30 4．橈腳類與仔稚魚的食階關係…………………………………30 肆、討論…………………………………………………………32 1．水文分析………………………………………………………32 2．物種與歧異度…………………………………………………34 3．物種組成與分佈………………………………………………35 4．再現群分析……………………………………………………39 5．優勢物種的相關分析…………………………………………40 6．指標物種分析…………………………………………………41 7．生物豐度的季節變化…………………………………………41 8．生物豐度與環境因數的關係…………………………………41 9．結論與研究方向………………………………………………42 伍、參考文獻……………………………………………………44 表…………………………………………………………………54 圖…………………………………………………………………61 附錄………………………………………………………………87
dc.language.iso	zh-TW
dc.title	臺灣海峽北部撓腳類與仔稚魚群集組成受水文因數之影響	zh_TW
dc.title	Variation of copepods and larval fishes driven by the hydrographic effects of northern Taiwan Strait	en
dc.date.schoolyear	89-2
dc.description.degree	碩士
dc.relation.page	101
dc.rights.note	未授權
dc.contributor.author-dept	生命科學院	zh_TW
dc.contributor.author-dept	動物學研究所	zh_TW
顯示於系所單位：	動物學研究所

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