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???org.dspace.app.webui.jsptag.ItemTag.dcfield??? | Value | Language |
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dc.contributor.advisor | 侯文祥 | |
dc.contributor.author | Yuan-Hsiou Chang | en |
dc.contributor.author | 張源修 | zh_TW |
dc.date.accessioned | 2021-06-08T07:01:20Z | - |
dc.date.copyright | 2009-04-20 | |
dc.date.issued | 2009 | |
dc.date.submitted | 2009-04-17 | |
dc.identifier.citation | 外文文獻
1.Barinaga, M., 1990. Where have all the froggies gone. Science. 247, 1033-1034. 2.Bergen, S.D., Bolton, S.M., Fridley, J.L., 1997. Ecological engineering: design based on ecological principles. ASAE Annual International Meeting. ASAE, USA., 49085-9659. 3.Bergen, S.D., Bolton, S.M., Fridley, J.L., 2001. Design principles for ecological engineering. Ecological Engineering. 18, 201-210. 4.Biesmeijer, J.C., Roberts, S.P.M., Reemer, M., Ohlemiller. R., Edwards, M., Peeters T., Schaffer, A.D., Potts, S.G., Keenkers, R., Thomas, C.D., Settele, J., Kumin, W.E., 2006. Parallel declines in pollinators and insect-pollinated plants in Britain and the Netherlands. Science. 313, 351-354. 5.Bikerman, J. J., 1971. Theory of adhesive joints. In N. Bikales(Ed.),adhesion and bonding. John Wiley, 35-40. 6.Blaustein, A. R., Wake, D. B., 1990. Declining amphibian populations: a global phenomenon. Trends in Ecology and Evolution. 5, 203-204. 7.Blaustein, A.R., Hoffman, P.D., Hokit, D.G., Kiesecker, J.M., Watts, S.C., Havs, J.B., 1994(a). UV repair and resistance to solar UV-B in amphibian eggs: a link to population declines. Proceedings of National Academyof Science. USA, 91, 1791-1795. 8.Blaustein, A.R., Wake, D.B., Sousa, W.P., 1994. Amphibian declines: judging stability, persistence, and susceptibility of populations to local and global extinctions. Conservation Biology. 8, 60-71. 9.Cadiergues, M. C., C. Joubert and M. Frane., 2000, A comparison of jump performances of the dog flea, Ctenocephalides canis (Curtis, 1826) and the cat flea, Ctenocephalides felis (Bouche, 1835). Veterinary Parasitology, 92: 239-241. 10.Dirzo, R., Raven, P.H., 2003. Global state of biodiversity and loss. Annu Rev Environ Resour. 28, 137–167. 11.Emerson, S. B., and Diehl, D., 1980, Toe pad morphology and mechanisms of sticking in frogs. Journal of the Linnean Society. 13, 199-216. 12.Fujioka, M., Lane, S. J., 1997. The impact of changing irrigation practices in rice fields on frog populations of the Kanto Plain, central Japan. Ecological Research. 12, 101-108. 13.Gillespie, G. R., 2002. Impacts of sediment loads, tadpole density, and food type on the growth and development of tadpoles of the spotted tree frog. Biological Conservation. 106, 141-150. 14.Green, D. M. and J. Carson., 1988. The adhesion of tree frog toe-pads to glass: cryogenic examination of a capillary adhesion system. Journal of Natural History. 22, 131-135. 15.Green, D. M., 1981, Adhesion and toe-pads of tree frogs. Copeia. 4, 790-796. 16.Hamer, A. J., S. J. Lane and M. J. Mahony, 2002. Management of freshwater wetlands for the endangered green and golden bell frog (Litoria aurea): roles of habitat determinants and space. Biological Conservation. 106, 413-424. 17.Hanna, G., and W. J. Barnes, 1991. Adhesion and detachment of the toe pads of tree frogs. Journal of Experiment Biological. 155, 103-125. 18.Hou, W. S., Chang Y. H., Wang, H. W., 2008. Climatic effects and impacts of lakeshore bank designs on the activity of Chirixalus idiootocus in Yilan, Taiwan, Ecological Engineering. 32, 52-59. 19.Hou, W. S., Chang, Y. H., Wang, H. W., Tan, Y. C., 2009. Using the Behavior of Seven Amphibian Species for the Design of Banks of Irrigation and Drainage Systems in Taiwan. The International Commission on Irrigation and Drainage. 20.Jansen, A., and Healey, M., 2003. Frog communities and wetland condition relationships with grazing by domestic livestock along an Australian floodplain river. Biological Conservation. 109, 207-219. 21.Kim, K. C., Byrne, L. B., 2006. Biodiversity loss and the taxonomic bottleneck: emerging biodiversity science. Ecological Research. 21, 794-810. 22.Kuo, C.C., 2006. Using ecotechnology to redirect Taiwan’s construction work away from conventional method. Ecological Engineering. 28, 325–332. 23.Kuramoto, M. and Wang, C. S., 1987. A new Rhacophorid Treefrog from Taiwan,with Comparisons to Chirixalus eiffingeri(Anura,Rhacophoridae). Copeia. 4, 931-942. 24.Laurance, W. F., 1996. Catastrophic declines of Australian rainforest frogs is unusual weather responsible. Biological Conservation. 77, 203-212. 25.Lee, W. J., K. Y. Lue and C. H. Lue, 2001. The SEM comparative study on toe among 19 species of tree frogs from Taiwan. BioFormosa. 36: 27-36. 26.Lemckert, F., 1999. Impacts of selective logging on frogs in a forested area of northern New South Wales. Biological Conservation. 89, 321-328. 27.Mitsch, W.J., 1996. Ecological engineering: a new paradigm for engineers and ecologists. In: Schulze, P.C. (Ed.), Engineering within Ecological Constraints. National Academy Press, Washington, DC, pp. 114-132. 28.Mitsch, W.J., Jorgensen, S.E., 1989. Introduction to ecological engineering, An Introduction to Ecotechnology. Wiley, New York, pp. 3–12. 29.Philips, K. 1990. Where have all the frogs and toads gone? BioScience. 40, 422-424. 30.Pounds, J. A., Crump, M. L., 1994. Amphibian declines and climate disturbance: the case of the golden toad and the harlequin frog. Conservation Biology. 8, 72- 85. 31.Seto, T., and Utsunomiya, T., 1987. Chromosome analysis of Hynobius arisanensis Maki, a salamander endemic to Taiwan. Herpetologica. 43(1):117-119. 32.Stenseth, N. C., Mysterud, A., Ottersen, G., Hurrel, J. W., Chan, K. S., Lima, M., 2002. Ecological effects of climate fluctuations. Science. 297, 1292–1296. 33.Turner, W. R., Nakamura, T., Dinetti, M., 2004. Global urbanization and the separation of humans from nature. Bioscience. 54, 585–590. 34.Wake, D. B., 1991. Declining amphibian populations. Science. 253- 860. 35.Wu, H.L., Feng, Z.Y., 2006. Ecological engineering methods for soil and water conservation in Taiwan. Ecological Engineering. 28, 333–344. 36.Wyman, R.L., 1990. What’s happening to the amphibians? Conservation Biology. 4, 350-352. 中文文獻 37.上野洋一郎,張淳文譯稿,1995,兩棲爬蟲動物世界。觀賞魚雜誌社,台北。 38.中國國家標準CNS10523,1987,門窗隔熱試驗法。 39.內政部建築研究所,2001,綠建築設計技術彙編。內政部建築研究所。 40.內政部建築研究所,2003,綠建築解說與評估手冊。內政部建築研究所。 41.呂光洋、林政彥、莊國碩,1990,臺灣區野生動物資料庫(一)兩棲類(Ⅱ)。行政院農委會,p.117-119。 42.呂光洋,1996,兩棲類動物資源調查手冊。行政院農委會,p.31-33。 43.呂光洋、杜銘章、向高世,1999,臺灣兩棲爬行動物圖鑑。中華民國自然生態保育協會,大自然雜誌社出版,p.343。 44.呂光洋,2005,阿里山地區阿里山山椒魚的分布和棲地利用之研究(3/4)—就地復育試驗。行政院農業委員會林務局委託研究系列第93-05-8-1 號。 45.巫奇勳,2002,溫泉與冷水域日本樹蛙蝌蚪的溫度耐受度與行為選溫之研究。彰化師範大學生物學研究所碩士論文,p.16-47。 46.李芬蘭,1985,盤古蟾蜍的行為研究。國立臺灣師範大學生物研究所碩士論文,p.16-47。 47.杜銘章、呂光洋,1982,十一種臺灣產兩棲類食性之研究(包括臺灣山椒魚) 。省立博物館年刊,25:225-234。 48.沈明來,2001,生物統計學入門。九州圖書文物有限公司,p.7-58。 49.林中一,2001,台北縣雙溪河流域褐樹蛙之生殖生態與族群分布。國立臺灣大學動物學研究所碩士論文,p.28。 50.林憲德,1999,城鄉生態。詹氏書局,p.6-7。 51.邱瓊平,2004,山椒魚不是魚!族群數量稀少值得用心呵護唷。東森新聞報。 52.邱繼哲,2002,建築物及生物成長設施之誘導式通風冷卻設計研究-以雙層外殼內置流動空氣層構造為例。國立臺灣大學生物環境系統工程學研究所碩士論文,p.57-58。 53.侯文祥、張源修,2004,水岸邊坡設計與面天樹蛙行為能力之關係研究。臺灣水利,52(2):49-57。 54.俞渭江,1976,生物統計附試驗設計。農業出版社,p.234-262。 55.張耀文,1989,面天樹蛙生殖行為之研究。國立臺灣大學動物學研究所碩士論文,p.12-54。 56.郭一羽,2001,水域生態工程。六合書局,p:254-275。 57.陳王時,2003,臺灣31種蛙類圖鑑。社團法人台北市野鳥學會,p.14-75。 58.陳世煌,1985,臺灣產山椒魚之生物學研究。國立臺灣師範大學生物學研究所碩士論文。 59.陳君翔,2006,臺灣阿里山山椒魚棲地狀況與生物活動力關係研究。國立臺灣大學生物環境系統工程研究所,碩士論文。 60.陳德治,1999,溫泉與冷水域日本樹蛙的生殖及其蝌蚪溫度生理學之比較。國立臺灣大學動物學研究所。 61.楊育昌,1996,酸鹼度對兩生類蝌蚪和胚胎發育的影響。國立臺灣大學動物學研究所。 62.葉明欽,1990,臺灣山椒魚棲地與族群變動之研究。國立臺灣師範大學生物學研究所,碩士論文。 63.蔡筱蕙 ,2003,面天樹蛙(Chirixalus idiootocus)卵粒的水分維持研究。國立臺灣師範大學生物學研究所碩士論文,p.13-30。 64.賴俊祥,1995,臺灣產山椒魚分類學研究。國立臺灣師範大學生物學研究所碩士論文。 65.賴勇志,2001,地震前後斯文豪氏赤蛙族群動態之研究。國立臺灣師範大學生物研究所碩士論文,p.27-28。 網站文獻 66.自然生活記趣,2009,http://blog.sina.com.tw/d100vs/。 67.呂光洋,2008,臺灣兩棲爬行動物生物多樣性,http://2008checklist.biodiv.tw/disc2008/doc/Kuang-Yang%20Lue.pdf,國立臺灣師範大學生命科學系。 68.李鵬翔、楊懿如,1999,青蛙學堂網站,http://www.froghome.idv.tw/index.htm。 69.廖添富,2003,臺灣鄉土兩棲類網站,http://databook.fhk.gov.tw/amphibian/index4.html,國立鳳凰谷鳥園。 70.臺灣大學動物博物館,2008,http://archive.zo.ntu.edu.tw/,國立臺灣大學。 | |
dc.identifier.uri | http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/26146 | - |
dc.description.abstract | 人為過度開發造成臺灣水岸混凝土化日益嚴重,但陸水共生之生物大部分生態系統行為多在水岸邊發生,臺灣目前尚無相關設計規範可供參考。本研究選擇八種涵蓋臺灣各地水域,與水岸環境密切的兩棲生物,探討其棲地與行為特性關係,期能改善水岸因混凝土化所造成之生物棲地破壞問題。實測其體長、體重、趾表面積、四肢攀爬能力、跳高與跳遠能力,以最適合的四種基質與對照組混凝土基質比較,配合五種邊坡坡度,量測兩棲類活動能力,依臺灣季節影響基質表面溫濕度的變化,探討對於兩棲類攀爬能力的影響。實驗結果得知,不論是在卵石或木質基質,於45°邊坡上日本樹蛙的單位體重攀爬能力只有面天樹蛙的16-17﹪。至於體型與行為能力之差異性,以同為赤蛙科之斯文豪氏蛙與腹斑蛙為例,雌性第一群中,斯文豪氏赤蛙較腹斑蛙在體重方面高63﹪;體長高30﹪;四肢肉趾表面積高44﹪;而行為能力方面,跳高能力高15﹪;跳遠能力高29﹪,可知同科別中,體型與行為能力有明顯差異。
在攀爬能力方面,兩棲類體型影響極大,依兩棲類體型由大而小,依序為盤古蟾蜍、褐樹蛙、拉都希氏赤蛙與日本樹蛙等作比較,大部分之兩棲類適應坡度能力,顯示應小於30°為佳。若將條件設定為木質邊坡30°,盤古蟾蜍幾乎無攀爬能力;日本樹蛙則高出褐樹蛙59﹪;褐樹蛙高出拉都希氏赤蛙67﹪。本研究之水岸邊坡基質與坡度組合,對於日後從事改造地方本土化水岸生態工程技術之相關工程人員能提供有用資料。 | zh_TW |
dc.description.abstract | The concreting process on water banks caused by inappropriate human development became a serious problem in Taiwan; however, most ecosystems of amphibian animals took place on lake banks, yet there was no related design solutions offered in Taiwan. This research selected eight species of amphibians in Taiwan. To discuss their habitats and behavioral characteristics in order to manage the problem of water banks. With measuring of each amphibian’s body length, weight, toe pad area, climbing ability, high jump ability, and long jump ability, this experiment was designed to compare concrete with four substrates which found most suitable in the experiment. Matching them with five appropriate bank angles to test amphibian’s motility, and furthermore, to identify the relation between amphibian’s abilities and surface substrates of water banks as humidity and temperature differ in four seasons. The result showed that if comparing per weight’s climbing ability of Chirixalus idiootocus and Buergeria japonicus, those two in the same family and of similar size, on the 15° bank slope, Buergeria japonicus’ climbing ability was only 17% of Chirixalus idiootocus’s on pebble substrate, but when the experiment was conducted on wood substrate, Buergeria japonicus’ climbing ability would down to 16% of Chirixalus idiootocus’s. If we took the example of Rana swinhoana and Rana adenopleura of Rana family to discuss their body sizes and behavioral ability’s differences, in the first female group, the weight of Rana swinhoana’s was 63% heavier than Rana adenopleura, as body length 30% longer than Rana adenopleura, and toe pad area 44% larger than Rana adenopleura. In the aspect of behavioral ability, Rana swinhoana performs 15% better in the field of high jump ability and 29% better with long jump. What was found in the results was that even in the same family, each amphibian may differ significantly in body size and behavioral ability. In the aspect of climbing ability , the body-size variable was an crucial factor, and if amphibians were ranked by size, the order was – Bufo bankorensis, Burgeria roubstus, Rana latouchii, and Buergeria japonicus – generally most amphibians adapted better on bank slope under 30°. Bufo bankorensis almost showed no climbing ability at the 30° slope, wooden bank, while Buergeria japonicus’ climbing ability was 59% stronger than that of Burgeria roubstus, and Burgeria roubstus’ climbing ability was 67% stronger than Rana latouchii’s. This research adopted multiple combinations of lake banks’ substrates and angles could serve as a reference for technicians’ in future ecological engineering on lake banks in Taiwan. | en |
dc.description.provenance | Made available in DSpace on 2021-06-08T07:01:20Z (GMT). No. of bitstreams: 1 ntu-98-F89622050-1.pdf: 2335003 bytes, checksum: eed309b91f2337f7d5e3bee19f8cf1e0 (MD5) Previous issue date: 2009 | en |
dc.description.tableofcontents | 授 權 書 I
口試委員 Ⅱ 會審定書 III 誌 謝 V 中文摘要 VI 英文摘要 VII 目 錄 VIII 圖 目 錄 X 表 目 錄 XII 第一章 緒論 1 1.1 研究動機與目的 1 1.2 研究對象與範圍 2 1.3 研究內容與流程 5 第二章 文獻回顧 8 2.1 臺灣地區氣候環境 8 2.2 臺灣兩棲類生理與棲地文獻探討 9 2.3 生物實驗相關理論 23 2.4 小結 29 第三章 材料與方法 31 3.1 兩棲類物種選定、取樣與分群方式 31 3.2 樣本之基本條件及行為能力量測 34 3.3 兩棲類在不同基質、角度及群別變化對攀爬能力之關係 37 3.4 模擬臺灣四季氣溫與基質含水率改變對於攀爬能力之影響 39 3.5 現地實測案例評估 41 3.6 統計分析檢定 42 3.7 生態工程設計模式建議 42 第四章 結果與討論 43 4.1 兩棲類之身體計量與行為能力量測結果 43 4.2 氣候環境對兩棲類利用不同基質、坡度活動能力影響 47 4.3 不同棲地條件兩棲生物對於水岸邊坡之條件需求 54 4.4 現地實測案例評估 62 4.5 生物統計分析檢定結果 69 4.6 綜合討論 94 4.7 生態工程邊坡設計剖面圖例 98 第五章 結論與建議 103 5.1 結論 103 5.2 建議 104 參考文獻 參考-1 附件一 兩棲類生物於不同基質之攀爬能力關係附件一-1 附件二 各項基質與角度之檢定分析數據 附件二-1 附件三 相同兩棲類物種於不同基質與不同角度之攀爬能力附件三-1 附件四 不同兩棲類物種於相同基質與不同角度之攀爬能力附件四-1 | |
dc.language.iso | zh-TW | |
dc.title | 以兩棲類活動能力探討水岸生態工程設計 | zh_TW |
dc.title | Using the Behavior of Amphibian for the Ecological Engineering Design of Aquatic Banks | en |
dc.type | Thesis | |
dc.date.schoolyear | 97-1 | |
dc.description.degree | 博士 | |
dc.contributor.oralexamcommittee | 張祖亮,陳 中,喻 新,黃裕益,呂光洋 | |
dc.subject.keyword | 生態工程,邊坡基質,攀爬能力,兩棲類,蛙, | zh_TW |
dc.subject.keyword | Ecological Engineering,Bank Substrate,Climbing Ability,Amphibian,Frog, | en |
dc.relation.page | 105 | |
dc.rights.note | 未授權 | |
dc.date.accepted | 2009-04-17 | |
dc.contributor.author-college | 生物資源暨農學院 | zh_TW |
dc.contributor.author-dept | 生物環境系統工程學研究所 | zh_TW |
Appears in Collections: | 生物環境系統工程學系 |
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