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研究生:梁晏榕
研究生(外文):Liang, Yan-Rong
論文名稱:比較大西洋重要經濟性鮪類豐度與棲地受氣候變異影響關係之研究
論文名稱(外文):Comparing the relationship between the abundance and habitats of the important economical tunas with climate variabilities in the Atlantic Ocean
指導教授:藍國瑋
指導教授(外文):Lan, Kuo-wei
口試委員:葉信明李明安張以杰
口試委員(外文):Yeh, Hsin-MingLee, Ming-AnChang, Yi-Jay
口試日期:2020-07-23
學位類別:碩士
校院名稱:國立臺灣海洋大學
系所名稱:環境生物與漁業科學學系
學門:農業科學學門
學類:漁業學類
論文種類:學術論文
論文出版年:2020
畢業學年度:108
語文別:中文
論文頁數:52
中文關鍵詞:大西洋棲地適合度指數經濟性鮪類種間競爭同步與非同步關係
外文關鍵詞:AtlanticHabitat suitability indexEconomical tunaCompetitionSynchronous and asynchronous relationship
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  • 被引用被引用:1
  • 點閱點閱:123
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謝辭 I
摘要 II
Abstract III
目錄 IV
圖目錄 V
表目錄 VI
壹、前言 7
1.1 臺灣鮪延繩釣漁業於大西洋概況 7
1.2 大西洋經濟性鮪類棲性與海洋環境之關係 7
1.3 氣候變異對鮪類豐度與分布之影響 8
1.4 研究動機與目的 9
貳、材料與方法 10
2.1 漁業資料蒐集、彙整與資料庫建立 10
2.1.1 台灣鮪延繩釣漁船漁獲資料 10
2.1.2 泛線性模式標準化CPUE 10
2.2 大西洋海洋環境資料與氣候變異指數 11
2.2.1 大西洋海洋環境資料 11
2.2.2 大西洋氣候變異指數 11
2.4 皮爾森相關性檢定(Pearson correlation) 12
2.5 偏最小平方迴歸(Partial least squares regression, PLS) 13
2.6 棲息地適合度指數 13
參、結果 15
3.1 大西洋經濟性鮪類漁獲概況 15
3.2 氣候變異指數對經濟性鮪類標準化CPUE、漁獲重心之影響 15
3.3 大西洋經濟性鮪類棲地環境與棲地適合度模式變動情形 16
3.4 氣候變異下經濟性鮪類棲地變動情形 16
肆、討論 18
4.1 大西洋經濟性鮪類分佈與豐度 18
4.2 氣候變異事件對經濟性鮪類棲地之影響 19
4.3 經濟性鮪類間的競爭關係 19
伍、結論及未來展望 21
5.1 結論 21
5.2 未來展望 21
參考文獻 22
Arrizabalaga, H., Dufour, F., Kell, L., Merino, G., Ibaibarriaga, L., Chust, G., ... & Chifflet, M. (2015). Global habitat preferences of commercially valuable tuna. Deep Sea Research Part II: Topical Studies in Oceanography, 113, 102-112.
Blanchard, J. L., Jennings, S., Holmes, R., Harle, J., Merino, G., Allen, J. I., ... & Barange, M. (2012). Potential consequences of climate change for primary production and fish production in large marine ecosystems. Philosophical Transactions of the Royal Society B: Biological Sciences, 367(1605), 2979-2989.
Carpenter, K. E., & Niem, V. H. (2001). FAO species identification guide for fishery purposes. The living marine resources of the Western Central Pacific. Volume 6. Bony fishes part 4 (Labridae to Latimeriidae), estuarine crocodiles, sea turtles, sea snakes and marine mammals. FAO species identification guide for fishery purposes. The living marine resources of the Western Central Pacific. Volume 6. Bony fishes part 4 (Labridae to Latimeriidae), estuarine crocodiles, sea turtles, sea snakes and marine mammals.
Chang, Y. J., Sun, C. L., Chen, Y., Yeh, S. Z., DiNardo, G., & Su, N. J. (2013). Modelling the impacts of environmental variation on the habitat suitability of swordfish, Xiphias gladius, in the equatorial Atlantic Ocean. ICES Journal of Marine Science, 70(5), 1000-1012.
Chavez, F. P., Ryan, J., Lluch-Cota, S. E., & Ñiquen, M. (2003). From anchovies to sardines and back: multidecadal change in the Pacific Ocean. Science, 299(5604), 217-221.
Chen, X., Li, G., Feng, B., & Tian, S. (2009). Habitat suitability index of Chub mackerel (Scomber japonicus) from July to September in the East China Sea. Journal of oceanography, 65(1), 93-102.
Collette, B. B., & Nauen, C. E. (1983). Scombrids of the world: an annotated and illustrated catalogue of tunas, mackerels, bonitos, and related species known to date. v. 2..
Dhurmeea, Z., Zudaire, I., Chassot, E., Cedras, M., Nikolic, N., Bourjea, J., ... & Bodin, N. (2016). Reproductive biology of albacore tuna (Thunnus alalunga) in the Western Indian Ocean. PLoS One, 11(12), e0168605.
Drinkwater, K. F. (2006). The regime shift of the 1920s and 1930s in the North Atlantic. Progress in Oceanography, 68(2-4), 134-151.
Dufour, F., Arrizabalaga, H., Irigoien, X., & Santiago, J. (2010). Climate impacts on albacore and bluefin tunas migrations phenology and spatial distribution. Progress in Oceanography, 86(1-2), 283-290.
Edwards, M., Beaugrand, G., Helaouët, P., Alheit, J., & Coombs, S. (2013). Marine ecosystem response to the Atlantic Multidecadal Oscillation. PloS one, 8(2).
Enfield, D. B., Mestas‐Nuñez, A. M., Mayer, D. A., & Cid‐Serrano, L. (1999). How ubiquitous is the dipole relationship in tropical Atlantic sea surface temperatures?. Journal of Geophysical Research: Oceans, 104(C4), 7841-7848.
Faillettaz, R., Beaugrand, G., Goberville, E., & Kirby, R. R. (2019). Atlantic Multidecadal Oscillations drive the basin-scale distribution of Atlantic bluefin tuna. Science advances, 5(1), eaar6993.
Frimodt, C. (1995) Multilingual illustrated guide to the world's commercial warmwater fish. Fishing News Books, Osney Mead, Oxford, England. 215 pp.
Gray, S. T., Graumlich, L. J., Betancourt, J. L., & Pederson, G. T. (2004). A tree‐ring based reconstruction of the Atlantic Multidecadal Oscillation since 1567 AD. Geophysical Research Letters, 31(12).
Hardin, G. (1960). The competitive exclusion principle. science, 131(3409), 1292-1297.
Hess, G. R. and J. M. Bay (2000). A regional assessment of windbreak habitat suitability. Environmental Monitoring and Assessment, 61(2): 237-254.
Hsu, C. C., Yeh, Y. M., & Liu, H. C.(2001). Age-specific abundance indices of yellowfin tuna for Taiwanese longline fishery in the Atlantic. ICCAT, 52 (1), 285-298.
Hu, C., Harrison, D. P., Hinton, M. G., Siegrist, Z. C., & Kiefer, D. A. (2018). Habitat analysis of the commercial tuna of the Eastern Tropical Pacific Ocean. Fish Oceanogr., 27(5), 417-434.
ICCAT (2001). Report of the ICCAT SCRS albacore stock assessment session. Collective Volume of Scientific Papers, ICCAT, 52, 1283-1390
ICCAT (2016). ICCAT Manual. International Commission for the Conservation of Atlantic Tuna. In: ICCAT Publications [on-line]. Updated 2016.
ICCAT (2019). Report of the Standing Committee on Research and Statistics (SCRS). ICCAT, 1-454
IOTC (2009). Report of the Twelfth Session of the Scientific Committee of the IOTC. IOTC-2009-SC-R[E], 1-90
Lan, K. W., Nishida, T., Lee, M. A., Lu, H. J., Huang, H. W., Chang, S. K., & Lan, Y. C. (2012). Influence of the marine environment variability on the yellowfin tuna (Thunnus albacares) catch rate by the Taiwanese longline fishery in the Arabian Sea, with special reference to the high catch in 2004. J. Mar. Sci. Technol., 20(5), 514-524.
Lan, K. W., Lee, M. A., Chou, C. P., & Vayghan, A. H. (2018). Association between the interannual variation in the oceanic environment and catch rates of bigeye tuna (Thunnus obesus) in the Atlantic Ocean. Fisheries Oceanography, 27(5), 395-407.
Lauver, C. L., Busby, W. H., & Whistler, J. L. (2002). Testing a GIS model of habitat suitability for a declining grassland bird. Environmental Management, 30(1), 88-97.
Lee, Y. C., Nishida, T., & Mohri, M. (2005). Separation of the Taiwanese regular and deep tuna longliners in the Indian Ocean using bigeye tuna catch ratios. Fisheries Science, 71(6), 1256-1263.
Lehodey, P., Bertignac, M., Hampton, J., Lewis, A., & Picaut, J. (1997). El Niño Southern Oscillation and tuna in the western Pacific. Nature, 389(6652), 715-718.
Lehodey, P., Chai, F., & Hampton, J. (2003). Modelling climate‐related variability of tuna populations from a coupled ocean–biogeochemical‐populations dynamics model. Fisheries Oceanography, 12(4‐5), 483-494.
Lehodey, P., Senina, I., & Murtugudde, R. (2008). A spatial ecosystem and populations dynamics model (SEAPODYM)–Modeling of tuna and tuna-like populations. Progress in Oceanography, 78(4), 304-318.
Marshall, J., Johnson, H., & Goodman, J. (2001). A study of the interaction of the North Atlantic Oscillation with ocean circulation. Journal of Climate, 14(7), 1399-1421.
Ménard, F., Stéquert, B., Rubin, A., Herrera, M., & Marchal, É. (2000). Food consumption of tuna in the Equatorial Atlantic ocean: FAD-associated versus unassociated schools. Aquatic living resources, 13(4), 233-240.
Milessi, A. C., Arancibia, H., Neira, S., & Defeo, O. (2005). The mean trophic level of Uruguayan landings during the period 1990–2001. Fisheries Research, 74(1-3), 223-231.
Nakagome, J. (1978). The study of relation between tuna and oceanography. Bull. Jap. Soc. Fish. Oceanogr, 44, 231-234.
Nikolic, N., Morandeau, G., Hoarau, L., West, W., Arrizabalaga, H., Hoyle, S., ... & Williams, A. J. (2017). Review of albacore tuna, Thunnus alalunga, biology, fisheries and management. Reviews in fish biology and fisheries, 27(4), 775-810.
Papastamatiou, Y. P., Wetherbee, B. M., Lowe, C. G., & Crow, G. L. (2006). Distribution and diet of four species of carcharhinid shark in the Hawaiian Islands: evidence for resource partitioning and competitive exclusion. Marine Ecology Progress Series, 320, 239-251.
Reid, P. C., de Fatima Borges, M., & Svendsen, E. (2001). A regime shift in the North Sea circa 1988 linked to changes in the North Sea horse mackerel fishery. Fisheries Research, 50(1-2), 163-171.
Servain, J., Wainer, I., McCreary Jr, J. P., & Dessier, A. (1999). Relationship between the equatorial and meridional modes of climatic variability in the tropical Atlantic. Geophysical Research Letters, 26(4), 485-488.
Sun, C. L., Huang, C. L., & Yeh, S. Z. (2001). Age and growth of the bigeye tuna, Thunnus obesus, in the western Pacific Ocean. Fish. Bull., 99(3), 502-502.
Teo, S. L., Boustany, A. M., & Block, B. A. (2007). Oceanographic preferences of Atlantic bluefin tuna, Thunnus thynnus, on their Gulf of Mexico breeding grounds. Marine Biology, 152(5), 1105-1119.
Tian, S., Chen, X., Chen, Y., Xu, L., & Dai, X. (2009). Evaluating habitat suitability indices derived from CPUE and fishing effort data for Ommatrephes bratramii in the northwestern Pacific Ocean. Fisheries Research, 95(2-3), 181-188.
Wold, S., Ruhe, A., Wold, H., & Dunn, III, W. J. (1984). The collinearity problem in linear regression. The partial least squares (PLS) approach to generalized inverses. SIAM Journal on Scientific and Statistical Computing, 5(3), 735-743.
Yeh, Y. M., & Chang, S. T. (2010). CPUE standardizations for Yellowfin tuna caught by Taiwanese longline fishery in the Indian ocean using generalized linear model (Vol. 40). IOTC-2010-WPTT.
Wu, Y. L., Lan, K. W., & Tian, Y. J. (2020). Determining the effect of multiscale climate indices on the global yellowfin tuna (Thunnus albacares) population using a time series analysis. Deep Sea Research Part II: Topical Studies in Oceanography, 104808.
Yen, K. W., Lu, H. J., Chang, Y., & Lee, M. A. (2012). Using remote-sensing data to detect habitat suitability for yellowfin tuna in the Western and Central Pacific Ocean. International Journal of Remote Sensing, 33(23), 7507-7522.
Yeh, Y. M., & Chang, S. T. (2010). CPUE standardizations for Yellowfin tuna caught by Taiwanese longline fishery in the Indian ocean using generalized linear model (Vol. 40). IOTC-2010-WPTT.
Young, J. W., Lansdell, M. J., Campbell, R. A., Cooper, S. P., Juanes, F., & Guest, M. A. (2010). Feeding ecology and niche segregation in oceanic top predators off eastern Australia. Marine Biology, 157(11), 2347-2368.
Yu W. Chen X. J. Yi Q. Chen Y. Zhang Y. (2015). Variability of suitable habitat of western winter-Spring cohort for neon flying squid in the Northwest Pacific under anomalous environments . PLoS ONE , 10 : e0122997 .
許建宗,1991。1991年(第二十二屆)大西洋鮪類資源保護委員會研究與統計常設委員會年會種類評估。中國水產,467:5-43
沈世傑、李信徹、邵廣昭、莫顯蕎、陳春暉、陳哲聰 (1993)。台灣魚類誌,國立台灣大學動物學系,960 頁。
林言修,2000。熱帶太平洋大目鮪釣魚況與垂直水溫結構變動關係之研究,國立臺灣海洋大學漁業科學系碩士論文,74頁
楊士賢,2002。北大西洋長鰭鮪資源豐度指標之標準化研究,國立台灣大學海洋研究所碩士論文,24頁
黃炫瑋,2009。台灣東北部海域鎖管漁場之適合度分析。國立臺灣海洋大學碩士論文,60頁
謝佳樺,2009。利用遙測及漁獲資料偵測中西太平洋正鰹分佈熱區。國立臺灣海洋大學碩士論文,77頁
陳昱宏,2015。氣候變異對印度洋大目鮪釣獲率與空間分佈之影響。國立臺灣海洋大學碩士論文,82頁
許又今,2016。氣候變遷對阿拉伯海黃鰭鮪空間分布之影響,國立臺灣海洋大學碩士論文,82頁
洪懿成,2017。利用多衛星遙測資料建立北太平洋長鰭鮪棲地適合度經驗模式。國立臺灣海洋大學,54頁
尤薏茵,2019。南大西洋長鰭鮪棲地模式建構之研究。國立臺灣海洋大學碩士論文,46頁
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