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完整後設資料紀錄
DC 欄位 | 值 | 語言 |
---|---|---|
dc.contributor.advisor | 謝志豪(Chih-hao Hsieh) | |
dc.contributor.author | Wei-Hsuan Teng | en |
dc.contributor.author | 鄧瑋萱 | zh_TW |
dc.date.accessioned | 2021-06-15T04:46:26Z | - |
dc.date.available | 2012-08-12 | |
dc.date.copyright | 2010-08-12 | |
dc.date.issued | 2010 | |
dc.date.submitted | 2010-08-04 | |
dc.identifier.citation | Alcaraz, M., E. Saiz, A. Calbet, I. Trepat, and E. Broglio. 2003. Estimating zooplankton biomass through image analysis. Marine Biology 143:307-315.
Andersen, T. and D. O. Hessen. 1991. Carbon, nitrogen, and phosphorus content of freshwater zooplankton. Limnology and Oceanography 36:807-814. Bartholomew, G. A. 1981. A matter of size: An examination of endothermy in insects and terrestrial vertebrates. John Wiley & Sons, New York.:45-78. Boudreau, P. R., L. M. Dickie, and S. R. Kerr. 1991. Body-size spectra of production and biomass as system-level indicators of ecological dynamics. Journal of Theoretical Biology 152:329-339. Brose, U., T. Jonsson, E. L. Berlow, P. Warren, C. Banasek-Richter, L. F. Bersier, J. L. Blanchard, T. Brey, S. R. Carpenter, M. F. C. Blandenier, L. Cushing, H. A. Dawah, T. Dell, F. Edwards, S. Harper-Smith, U. Jacob, M. E. Ledger, N. D. Martinez, J. Memmott, K. Mintenbeck, J. K. Pinnegar, B. C. Rall, T. S. Rayner, D. C. Reuman, L. Ruess, W. Ulrich, R. J. Williams, G. Woodward, and J. E. Cohen. 2006a. Consumer-resource body-size relationships in natural food webs. Ecology 87:2411-2417. Brose, U., R. J. Williams, and N. D. Martinez. 2006b. Allometric scaling enhances stability in complex food webs. Ecology Letters 9:1228-1236. Brown, J. H., J. F. Gillooly, A. P. Allen, V. M. Savage, and G. B. West. 2004. Toward a metabolic theory of ecology. Ecology 85:1771-1789. Burkhardt, S., I. Zondervan, and U. Riebesell. 1999. Effect of CO2 concentration on C : N : P ratio in marine phytoplankton: A species comparison. Limnology and Oceanography 44:683-690. Cairns, J., P. V. McCormick, and B. R. Niederlehner. 1993. A proposed framework for developing indicators of ecosystem health Hydrobiologia 263:1-44. Chen, Y.-L. L., H.-Y. Chen, G.-C. Gong, Y.-H. Lin, S. Jan, and M. Takahashi. 2004. Phytoplankton production during a summer coastal upwelling in the East China Sea. Continental Shelf Research 24:1321-1338. Cohen, J. E., T. Jonsson, and S. R. Carpenter. 2003. Ecological community description using the food web, species abundance, and body size. Proceedings of the National Academy of Sciences of the United States of America 100:1781-1786. Cohen, J. E., S. L. Pimm, P. Yodzis, and S. J. 1993. Body sizes of animal predators and animal prey in food webs. Journal of Animal Ecology 62:67-78. Cushing, D. H. 1975. Marine ecology and fisheries Cambridge University Press, Cambrige. Damuth, J. 1981. Population density and body size in mammals. Nature 290:699-700. Emmerson, M. C. and D. Raffaelli. 2004. Predator-prey body size, interaction strength and the stability of a real food web. Journal of Animal Ecology 73:399-409. Frenette, J.-J., W. F. Vincent, and L. Legendre. 1998. Size-dependent C: N uptake by phytoplankton as a function of irradiance: Ecological implications. Limnology and Oceanography 43:1362-1368. Fry, B. 2006. Stable isotope ecology. Springer. Fry, B. and R. B. Quinones. 1994. Biomass spectra and stable isotope indicators of trophic level in zooplankton of the northwest Atlantic. Marine Ecology-Progress Series 112:201-204. Fry, B. and E. B. Sherr. 1984. δ 13 C measurements as indicators of carbon flow in marine and freshwater ecosystems. Contributions in Marine Science 27:13-47. Gannon, J. E. and R. S. Stemberger. 1978. Zooplankton (especially crusta- ceans and rotifers) as indicators of water quality. Transactions of the American Microscopical Society 97:16-35. Gong, G.-C. and G.-J. Liu. 2003a. An empirical primary production model for the East China Sea. Continental Shelf Research 23:213-224. Gong, G. C., F. K. Shiah, K. K. Liu, Y. H. Wen, and M. H. Liang. 2000. Spatial and temporal variation of chlorophyll a, primary productivity and chemical hydrography in the southern East China Sea. Continental Shelf Research 20:411-436. Gong, G. C., Y. H. Wen, B. W. Wang, and G. J. Liu. 2003b. Seasonal variation of chlorophyll a concentration, primary production and environmental conditions in the subtropical East China Sea. Deep-Sea Research Part Ii-Topical Studies in Oceanography 50:1219-1236. Hairston, N. G. 1993. Cause-effect relationships in energy flow, trophic structure, and interspecific interactions. American Naturalist 142:379-411. Healey, F. P. and L. L. Hendzel. 1980. Physiological indicators of nutrient deficiency in lake phytoplankton. Canadian Journal of Fisheries and Aquatic Sciences 37:442-453. Hecky, R. E., P. Campbell, and L. L. Hendzel. 1993. The stoichiometry of carbon, nitrogen, and phosphorus in particulate matter of lakes and oceans. Limnology and Oceanography 38:709-724. Hemmingsen. 1960. Energy metabolism as related to body size and respiratory surfaces and its evolution. Reports of the Steno Memorial Hospital and Nordisk Insulin Laboratorium 9:6-110. Hewitt, J. E., M. J. Anderson, and S. F. Thrush. 2005. Assessing and monitoring ecological community health in marine systems. Ecological Applications 15:942-953. Jennings, S. and K. J. Warr. 2003. Smaller predator-prey body size ratios in longer food chains. Proceedings of the Royal Society of London Series B-Biological Sciences 270:1413-1417. Jennings, S., K. J. Warr, and S. Mackinson. 2002. Use of size-based production and stable isotope analyses to predict trophic transfer efficiencies and predator-prey body mass ratios in food webs. Marine Ecology-Progress Series 240:11-20. Jonsson, T. and B. Ebenman. 1998. Effects of Predator-prey Body Size Ratios on the Stability of Food Chains. Journal of Theoretical Biology 193:407-417. Kerr, S. R. and L. M. Dickie. 2001. The biomass spectrum: a predator-prey theory of aquatic production. Cambridge University Press, Cambrige. Kleiber, M. 1947. Body size and metabolic rate. Physiol. Rev. 27:511-541. Kleppel, G. S., D. Frazel, R. E. Pieper, and D. V. Holliday. 1988. Natural diets of zooplankton off southern California. Marine Ecology-Progress Series 49:231-241. Landry, M. R. 1978. Population dynamics and production of a planktonic marine copepod, Acartia clausii, in a small temperate lagoon on San Juan Island, Washington. Internationale Revue der gesamten Hydrobiologie und Hydrographie 63:77-119. Laws, E. A. and T. T. Bannister. 1980. Nutrient-and light-limited growth of Thalassiosira fluviatilis in continuous culture, with implications for phytoplankton growth in the ocean. Limnology and Oceanography 25:457-473. Liu, K.-K., T. Yung Tang, G.-C. Gong, L.-Y. Chen, and F.-K. Shiah. 2000. Cross-shelf and along-shelf nutrient fluxes derived from flow fields and chemical hydrography observed in the southern East China Sea off northern Taiwan. Continental Shelf Research 20:493-523. Montagnes, D. J. S., J. A. Berges, P. J. Harrison, and F. J. R. Taylor. 1994. Estimating carbon, nitrogen, protein, and chlorophyll a from volume in marine phytoplankton. Limnology and Oceanography 39:1044-1060. Neutel, A.-M., J. A. P. Heesterbeek, J. van de Koppel, G. Hoenderboom, A. Vos, C. Kaldeway, F. Berendse, and P. C. de Ruiter. 2007. Reconciling complexity with stability in naturally assembling food webs. Nature 449:599-602. Nilsson, P. A. and C. Bronmark. 2000. Prey vulnerability to a gape-size limited predator: behavioural and morphological impacts on northern pike piscivory. Oikos 88:539-546. Nixon, S. W., J. W. Ammerman, L. P. Atkinson, V. M. Berounsky, G. Billen, W. C. Boicourt, W. R. Boynton, T. M. Church, D. M. Ditoro, R. Elmgren, J. H. Garber, A. E. Giblin, R. A. Jahnke, N. J. P. Owens, M. E. Q. Pilson, and S. P. Seitzinger. 1996. The fate of nitrogen and phosphorus at the land sea margin of the North Atlantic Ocean. Biogeochemistry 35:141-180. Peters, R. H. 1983. The ecological implications of body size. Cambridge University Press, Cambrige. Peterson, B. J. and B. Fry. 1987. Stable isotopes in ecosystem studies. Annual Review of Ecology and Systematics 18:293-320. Peterson, B. J., R. W. Howarth, and R. H. Garritt. 1985. Multiple stable isotopes used to trac the flow of organic matter in estuarine food web. Science 227:1361-1363. Pimm, S. L. 2002. Food Webs. The University of Chicago Press, Chicago. Polis, G. A. and D. R. Strong. 1996. Food web complexity and community dynamics. American Naturalist 147:813-846. Post, D. M. 2002a. The long and short of food-chain length. Trends in Ecology & Evolution 17:269-277. Post, D. M. 2002b. Using stable isotopes to estimate trophic position: Models, methods, and assumptions. Ecology 83:703-718. Post, D. M., M. L. Pace, and N. G. Hairston. 2000. Ecosystem size determines food-chain length in lakes. Nature 405:1047-1049. Poulet, S. A. and R. Williams. 1991. Characteristics and properties of copepods affecting the recruitment of fish larvae. Bulletin of the Plankton Society of Japan Special 271-290. Rolff, C. and R. Elmgren. 2000. Use of riverine organic matter in plankton food webs of the Baltic Sea. Marine Ecology-Progress Series 197:81-101. Scharf, F. S., F. Juanes, and R. A. Rountree. 2000. Predator size - prey size relationships of marine fish predators: interspecific variation and effects of ontogeny and body size on trophic-niche breadth. Marine Ecology-Progress Series 208:229-248. See, J. H., L. Campbell, T. L. Richardson, J. L. Pinckney, R. J. Shen, and N. L. Guinasso. 2005. Combining new technologies for determination of phytoplankton community structure in the northern Gulf of Mexico. Journal of Phycology 41:305-310. Sheldon, R. W., A. Prakash, and W. H. Sutcliffe, Jr. 1972. The size distribution of particles in the ocean. Limnology and Oceanography 17:327-340. Speakman, J. R. 2005. Body size, energy metabolism and lifespan. J Exp Biol 208:1717-1730. Sprules, W. G. 1972. Effects of size-selective predation and food competition on high altitude zooplankton communities. Ecology 53:375-386. Sterner, R. W. and J. J. Elser. 2002. Ecological stoichiometry: the biology of elements from molecules to the biosphere. Princeton University Press, Princeton and Oxford. Syv, J. ranta, M. Tiirola, and R. I. Jones. 2008. Seasonality in lake pelagic 15N values: patterns, possible explanations, and implications for food web baselines. Fundamental and Applied Limnology / Archiv für Hydrobiologie 172:255-262. Tsai, A.-Y., K.-P. Chiang, J. Chang, and G.-C. Gong. 2005. Seasonal Diel Variations of Picoplankton and Nanoplankton in a Subtropical Western Pacific Coastal Ecosystem. Limnology and Oceanography 50:1221-1231. Uye, S.-i. 1982. Length-weight relationships of important zooplankton from the Inland Sea of Japan. Journal of Oceanography 38:149-158. Vargas, C. A., L. A. Cuevas, H. E. Gonzalez, and G. Daneri. 2007. Bacterial growth response to copepod grazing in aquatic ecosystems. Journal of the Marine Biological Association of the United Kingdom 87:667-674. Voros, L. and J. Padisak. 1991. Phytoplankton biomass and chlorophyll-a in some shallow lakes in central Europe. Hydrobiologia 215:111-119. West, G. B., J. H. Brown, and B. J. Enquist. 2001. A general model for ontogenetic growth. Nature 413:628-631. Woodward, G., B. Ebenman, M. Emmerson, J. M. Montoya, J. M. Olesen, A. Valido, and P. H. Warren. 2005. Body size in ecological networks. Trends in Ecology & Evolution 20:402-409. Zimmerman, M. 1981. Optimal foraging, plant density and the marginal value theorem. Oecologia 49:148-153. | |
dc.identifier.uri | http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/45804 | - |
dc.description.abstract | 人為干擾及氣候變遷對生態系的協同效應日益受到關注,因此我們急需一套有效率且可信賴的指標來研究食物網的動態,並用來做為生態系統監測及保育的基礎。大型生物捕食小型生物在水生環境系統中是非常普遍的現象,因此利用生物個體大小為理論基礎來探討水生生態系統動態是一個潛在的指標。有許多文獻指出生物個體體型大小以及營養階層之間存在著良好的線性關係,然而支持此現象的研究證據大多數僅侷限於大型生物所形成之食物網,然而此種線性關係是否存在於浮游生物群聚中至今仍然沒有明確的定論。捕食者與獵物之間體型大小的比例是決定食物網結構、穩定性及動力學的重要參數,然而直到現在探討何種機制影響捕食者與獵物體型大小比例的研究非常有限。本研究假設資源可利用性為影響捕食者與獵物體型大小比例變異之重要因子,並且提出利用(1)環境中物理及營養鹽參數、(2)浮游植物生物量,以及(3)顆粒性有機物質之碳氮比,來作為資源可利用性的代用指標。本研究藉由碳氮穩定同位素分析來探討在不同環境下浮游生物各體型組距間的食階關係,以及捕食者和獵物之間的交互作用。本研究結果顯示在大型浮游生物群聚中,體型大小及營養階層之間仍然存在明顯的正相關性;然而在小型浮游生物群聚中,體型大小和營養階層之間正相關性非常薄弱,甚至有反向的關係發生。本研究也指出捕食者與獵物體型大小比例在生態系統中確實會受到某些特定因素的影響,例如: (1)捕食者與獵物體型大小比例有空間上的變異。在相對變動較大的沿岸環境中,捕食者與獵物體型大小比例不會有太大的變動;而捕食者與獵物體型大小比例在外洋環境中卻存在有非常大的變異性。(2)捕食者與獵物體型大小比例會隨著浮游植物總生物量增加而呈現了非線性的下降趨勢。(3)食物來源的品質(元素組成)對於捕食者與獵物體型大小比例會產生影響。最後,在結合體型大小和食物階層關係以及捕食者與獵物體型大小比例之分析當中發現,在捕食者與獵物體型大小比例較小的時候,生態系統中會有較長的食物鏈;而較小的捕食者與獵物體型大小比例通常發生在環境變異較大的沿岸環境中。 | zh_TW |
dc.description.abstract | Effects of anthropogenic disturbance and global climate changes on ecosystems are pressing concerns. Developing reliable and efficient indicators to study trophodynamics is essential for ecosystem management and conservation. Aquatic food webs are strongly size-based; therefore, one potential indicator to investigating trophodynamics is variation in body size. Substantial evidence suggests a positive linear relationship between log size and trophic level; however, whether such positive relationship holds in plankton community remains elusive. Predator-prey mass ratio (PPMR) is an important parameter to determine the stability, structure and dynamic of foodweb. Nevertheless, only one mechanism (gape limitation) was proposed to explain the observed pattern in predator-prey body mass ratios (PPMR) so far. We hypothesized and tested that PPMR was sensitive to the variation of resource availability and used three factors as proxy for resource availability: (1) concentration of nutrient; (2) phytoplankton biomass; and (3) C:N ratio of particulate organic matter. The present study used stable isotope analysis to assess size-TL relationship and PPMR within plankton communities. Our result suggested that larger size plankton community generally showed a strong linear positive size-TL relationship, but the small size plankton community showed non-significant and sometimes even inverse pattern. The present result also manifested some patterns in the PPMR. First, PPMR was steady in highly changeable costal environments; by contrast, PPMR were relatively variable in stable offshore environments. Second, PPMR showed a nonlinear declining trend with an increase in total phytoplankton biomass. Third, food quality has influence on PPMR. Coupled analyses of size-TL and PPMR may provide a basis for assessing the structure of food webs. Our result indicated that longer food chains were found in the food webs where average PPMR were smaller, and mean PPMR were smaller in highly variable inshore environments. | en |
dc.description.provenance | Made available in DSpace on 2021-06-15T04:46:26Z (GMT). No. of bitstreams: 1 ntu-99-R97241201-1.pdf: 1394954 bytes, checksum: 9afee43d4c6b1562c94ec677253b9dd8 (MD5) Previous issue date: 2010 | en |
dc.description.tableofcontents | Contents
摘要 i Abstract iii Contents v List of Tables vii List of Figures viii Introduction 1 Materials and methods 7 Study area 7 Field sampling 8 Stable isotope analysis 9 Trophic position estimation 11 Convert from lengths to carbon 12 The size-specific trophic level 12 Predator-prey mass ratio (PPMR) 13 Resource availability 13 (1) Concentration of nutrient and chlorophyll a 13 (2) Phytoplankton biomass 13 (3) C:N ratio of POM 14 Food chain length 15 Data analysis 15 Result 16 Hydrography 16 Taxonomic composition of each size class 16 Body size and trophic level relationship 17 Predator-prey mass ratio 18 Predator-prey mass ratio and environmental condition 19 Predator-prey mass ratio and phytoplankton biomass 19 C:N ratio of plankton community 20 Predator-prey mass ratio and C:N ratio of POM 20 Predator-prey mass ratio and food chain length 21 Discussion 22 Relationship between body size and trophic level 22 Spatial variation of nitrogen stable isotope signature 23 Changes in PPMR with environmental variations. 24 Stoichiometry, body size and PPMR 25 Studying trophodynamics using PPMR 28 The bottleneck of PPMR 29 Conclusion 30 References 32 Appendix 61 | |
dc.language.iso | en | |
dc.title | 利用穩定同位素探討浮游動物之個體大小與營養階層關係在不同水生生態系統下的變動 | zh_TW |
dc.title | Investigation of size-trophic level relationships of zooplankton in different ocean environments-a stable isotope approach | en |
dc.type | Thesis | |
dc.date.schoolyear | 98-2 | |
dc.description.degree | 碩士 | |
dc.contributor.oralexamcommittee | 溫良碩,龔國慶,蔣國平 | |
dc.subject.keyword | 穩定同位素,體型大小及營養階層關係,捕食者與獵物體型大小比例,資源可利用性,碳氮比,個體大小頻譜,食物鏈長度, | zh_TW |
dc.subject.keyword | stable isotope,size-TL relationship,PPMR,food availability,C:N ratio,size spectra,food chain length, | en |
dc.relation.page | 65 | |
dc.rights.note | 有償授權 | |
dc.date.accepted | 2010-08-05 | |
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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