復育物種選擇之研究 - 以蓮華池地區為例

Chun-Jheng Yang; 楊淳正

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/61019

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	邱祈榮
dc.contributor.author	Chun-Jheng Yang	en
dc.contributor.author	楊淳正	zh_TW
dc.date.accessioned	2021-06-16T10:41:45Z	-
dc.date.available	2016-08-23
dc.date.copyright	2013-08-23
dc.date.issued	2013
dc.date.submitted	2013-08-13
dc.identifier.citation	柒、參考文獻王金錫、王啟和、孫鵬、蒲春齡、陸元昌 (2007)。退化天然常綠闊葉林近自然林經營技術研究(一)。四川林業科技 28(2):7-14。台灣植物誌第二版編輯委員會 (1993-1998)。台灣植物誌第二版第2~4卷。沈有信、劉文耀、李玉輝、崔建武 (2005)。滇中喀斯特地形山地半濕潤常綠闊葉林的群落生態學研究。廣西植物 25(4):321-326。冶民生、吳斌、關文斌、馬克明、劉國華、張宇清 (2009)。岷江源區植物群落複雜性研究。乾旱區資源與環境 23(8):174-179。邱清安、曾喜育、王俊閔、吳佾鴻、曾彥學 (2012)。東勢林場植物資源調查及其生態復育芻議。林業研究季刊 34(1)13-38。邱祈榮，陳子英，謝長富，劉和義，葉慶龍，王震哲 (2010)。台灣現生天然植群圖集。林務局，台北市 419頁。林文賜、馮梓懸、周文杰、林昭遠、黃碧慧 (2007)。崩塌地對生態環境影響之評估-以九份二山崩塌地為例。明道學術論壇 3(2):27-48。邱創益、陳慶雄、謝杉周 (1992)。和平水泥專業區綠帶及礦區植生復舊之研究。經濟部工業局。胡大中、應紹舜 (2004)。明德水庫集水區次生林植群之研究。台大實驗林研究報告18(4):285-301。唐志堯、方精云、張玲(2004)。秦嶺太白山木本植物物種多樣性的梯度格局及環境解釋。生物多樣性 12(1)：115-122。章家恩、徐琪 (1999)。退化生態系統的診斷特徵及其評價指標體系。長江流域資源與環境 8(2):215-220。馬克平 (1993)。試論生物多樣性的概念。生物多樣性 1(1):20-22。陳意昌、林信輝 (2005)。礦區植生工法、生態綠化與棲地改善。礦區規劃開發與自然生態工法宣導會經濟部礦物局。陳志豪、鄭旭涵、彭心燕、林信輝 (2010)。崩塌地植生復育適用評估因子之分析研究。中華水土保持學報 41(4):296-307 湯孟平、周國模、施擁軍、陳永剛、吳亞琪、趙明水 (2006)。天目山常綠闊葉林群落最小取樣面積與物種多樣性。浙江林學院學報 23(4):357-361。張勵婉、黃正良、陳意婷、葉秋妤、林奐慶、郭志荃等人 (2012)。蓮華池亞熱帶常綠闊葉森林動態樣區:樹種特徵及其分布模式。農委會林試所印行台北市。360頁。葉慶龍、陳子英、宋梧魁 (2004)。南仁山區相思樹人工林於演替序列上物種多樣性之研究。台大實驗林研究報告 18(3):229-246。劉蔚秋、余世孝、王永繁、練琚蒲 (2003)。粵西黑石頂自然保護區杉木林與賜生常綠闊葉林群落特徵比較。內蒙古大學學報(自然科學版) 34(3):318-324。劉棠瑞、蘇鴻傑 (1983)。森林植物生態學。台灣商務印書館 462頁。劉燦然、馬克平、陳靈芝 (1996)。群落最小面積的概念及其確定方法。生物多樣性與人類未來-第二屆全國生物多樣性保護與持續利用討論會論文集中國科學院植物研究所北京。賴明洲 (2007)。植被復育重建生態工程。明文書局台北市 567頁。蘇鴻傑 (2004)。植群之多樣性及多樣化之分類法。台大實驗林研究報告18(3): 207-220。魏聰輝、賴彥任、張振生、陳信雄、林博雄 (2008)。溪頭地區崩塌地人工植群復育過程之熱量收支。作物、環境與生物資訊 5:217-226。謝蕙蓮、賴瑋倩 (2006)。《國土復育篇》找回溼地　維護生物多樣性。營建知訊286:12-25。 Akaike, H. (1973) Information theory as an extension of the maximum likelihood principle. In: Second International Symposium on Information Theory (B.N. Petrov & F. Csaki, eds),pp. 267–281. Akademiai Kiado, Budapest. Carins, JR. (1995) Encyclopedia of environmental Biology, 3:223-235 Chang, L.W., S.T. Chiu, K. C. Yang, H. H. Wang, J.L. Hwong, and C. F. Hsieh. (2012) Changes of plant communities classification and species composition along the micro-topography at the lienhuachih forest dynamics plot in the central Taiwan. Taiwania,57(4):359-371. Chapman, G P. (1992) Desertified grassland. London:Academic Press,pp. 8-12. Cody, M.L. (1993) Bird diversity components within and between habitats in Australia. Speciesdiversity in ecological communities: historical and geographical perspectives (ed. by R.E.Ricklefs and D. Schluter), pp. 147-158. University of Chicago Press, Chicago, IL. Condit, R. (1998) Tropical forest census plot. New York: Springer-Verlag. Daily, G C. (1995) Restoring value to the worlds degraded lands. Science, 269:350-354. Ferreira, P. M. A. and Boldrini Ilsi I. (2011) Potential reflection of distinct ecological units in plant endemism categories. Conservation Biology, 25(4):672-679. Fisher, R. A., A. S. Corbet, and C. B. Williams. (1943) The relation between the number of species and the number of individuals in a random sample of an animal population. The Journal of Animal Ecology, 12(1): 42-58. Gonzalez, E. E., R. H. Fawcett, M. Herrero. (2002) Integrating models of relative abundance of species with the dry-weight-rank method for the botanical analysis of forest understorey vegetation. Grass and Forage Science, 57(2):171-183. Lu, H.P., Helene H. Wagner, and X.Y. Chen. (2007) A contribution diversity approach to evaluate species diversity. Basic and Applied Ecology, pp.1-12 Kindt, R., and C. Richard. (2005) Tree diversity analysis: a manual and software for common statistical methods for ecological and biodiversity studies. World Agrofirestry Centre, 196pp. Larrivee, M., and C. M. Buddle. (2009) Diversity of canopy and understorey spiders in north-temperate hardwood forests. Agricultural and Forest Entomology, 11:225-237. Liu, G. H., Fu B. J., Chen L. D.,X.D.Guo. (2000) Characteristics and distributions of degraded ecological types in China. Acta Ecologica Sinica, 20(1):13-19 Jordan, W.R. III. (1995) Sunflower Forest : ecological restoration as the basis for a new environmental paradigm. InL Baldwin ADJ, ed. Beyond presevation: restoring and inventing landscape. Minneapolis: Unicersilty of Minnesota Press, pp.17-34 MacArthur, R. H. (1957) On the relative abundance of bird species. Proc. Nat. Acad. Sci. U.S.A., 43:293-295 Magurran, A. E. (1988) Ecological Diversity and Its Measurement. Princeton University Press, Princeton, New Jersey. 192pp. Matossian, A. D., Y. G. Matsinos, P. Konstantinidis, and A. Moustakas. (2013) Post-fire succession indices performance in a Mediterranean ecosystem. Stoch Environ Res Risk Assess, 27:323-335. McCune, B. and M.J. Mefford. (1999) PC-ORD. Multivariate analysis of ecological data, Version 4. MjM Software Design, Gleneden Beach, OR, USA. 237pp. Miyawaki, A. (2004) Restoration of living environment based on vegetation ecology: theory and practice. Ecological Reseach, 19:83-90. Motomura, I. (1932) A statistical treatment of associations; in Japanese. Jap.J.Zool, 44:379-383 Motomura, I. (1947) Further notes on the law of geometrical pregression of the population density in animal association; in Japanese. Physiol. Ecol, 1:55-60 Peng, S. L. (2003) Study and application of restoration ecology in tropical and subtropical china. Beijing: Science Press, pp.1-25 R Development Core Team (2008). R: A language and environment for statistical computing. R Foundation for Statistical Computing, Vienna, Austria. ISBN 3-900051-07-0, URL http://www.R-project.org. Ren, H., and S. L. Peng. (1998) Restoration and rebuilding of degraded ecosystem. Youth Geography, 3(3):7-11 Scheiner, S.M. (2008). Six types of species-area curves. Global Ecology and Biogeography, 12: 441-7 Shannon, C.E.,W. Wiener, (1963) The mathematical theory of communications, Univ. Illinois, Urbana. 117 pp. Simpson, E. H. (1949) Measurement of diversity. Nature, 163: 688. Tuhkanen, S. (1980) Climatic parameters and indices in plant geography. Almqvist & Wiksell International, Uppsala, Sweden. Vleut, I., I.L.-T. Samuel, J.G.Gonzalez, W. F. De Boer and N. Ramirez-Marcial. (2012) Tropical rain-forest matrix quality affects bat assemblage structure in secondary forest patches. Journal of Mammalogy, 93(6):1469-1479. Whittaker, R. H. (1960) Vegetation of the siskiyou mountains, oregon and california. Ecological Monographs, 30(3): 279-338. Whittaker, R. H. (1965) Dominance and diversity in land plant communities. Science, 147:250-260. Whittaker, R. H. (1972) Evolution and measurement of species diversity. Taxon, 21:213-251. Wilson, J. B. (1991) Methods for fitting dominance/diversity curves. Journal of Vegetation Science, 2:35-46.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/61019	-
dc.description.abstract	復育生態學在世界上已經成為生態學上重要的學科之一，但台灣在植群復育作業的物種選擇上缺乏客觀的操作標準，於是本研究選擇了台灣中部低海拔保存最完整的天然闊葉林及受到開發為人工林、果園等人為干擾的蓮華池地區作為研究目標，嘗試以蓮華池地區的物種分布型態為案例提出在此地進行植相復育時物種與植群型的建議。本研究透過蓮華池樣區與植群樣區的代表性研究得出在復育地為中心半徑15km內設置30個樣區可初步建構該地的代表性植群，並將樣區資料進行分群，蓮華池動態樣區經過分群可分為2型9亞型；植群樣區則可分為2型7亞型。利用多樣性指數及多樣性貢獻度找出地區中屬於普通狀態的樣區及特殊狀態的樣區，再透過擬合物種豐度模型將樣區演替程度進行分類，依照復育目標找出樣區內較理想的植群型態，最後配合植群型及其物種進行復育規劃。	zh_TW
dc.description.abstract	Restoration ecology has been an important science in the world, but there was not an objective rule to chose species in restoration procedure in Taiwan. This object chose the most protected natural forest at low altitude in Lienhuachih lake reigion which has artificial forest, orchard and landslide part as our research target. Trying to build a guide of species choosing when planning a restoration project. According to the representive research, we find that taking 30 plots arround the restoration place in 15km radius can construct the typical vegetation type.And make the Lienhuachih forest dynamics plots into 2 association and 9 subassociation, also the vegetation map plots into 2 association and 7 subassociation. Than we use diversity ordering and diversity contribution of samples to find the normal type stand and unique type stand in our plots. We use species abundance model to reclass plots into different succession stages, finding the most valueable sample to be the examplar. After all we use these information to give suggestion to the procedure of rebuilding a ecosystem.	en
dc.description.provenance	Made available in DSpace on 2021-06-16T10:41:45Z (GMT). No. of bitstreams: 1 ntu-102-R99625017-1.pdf: 2190520 bytes, checksum: c41d5e60cef42de3e2fd974f43941160 (MD5) Previous issue date: 2013	en
dc.description.tableofcontents	目錄摘要 i Abstract ii 目錄 iii 表目錄 iv 圖目錄 iv 壹、前言 1 一、研究動機: 1 二、研究目的: 2 三、研究流程: 3 貳、前人研究 4 一、植群生態學 4 二、退化生態系與復育生態學 6 三、物種面積曲線與取樣最小面積 10 四、物種多樣性理論 11 五、物種豐度模型 17 參、材料與方法: 20 一、樣區概述及調查方法 20 二、資料統計與分析 24 A、樣區代表性分析 24 B、植群型分類 24 C、多樣性貢獻度計算 25 D、Renyi多樣性 26 E、樣區物種豐度模型 26 三、執行復育計畫建議流程 29 肆、結果與討論: 30 一、樣區基本性質、樣區代表性及最小調查面積 30 二、植物社會分類 38 三、多樣性分析結果 45 A、多樣性貢獻度分析 45 B、Renyi多樣性分析 47 C、物種豐度模型 48 D、綜合討論 53 伍、結論 56 陸、未來展望 58 柒、參考文獻 59 捌、附錄 64
dc.language.iso	zh-TW
dc.subject	生態復育	zh_TW
dc.subject	退化生態系	zh_TW
dc.subject	多樣性	zh_TW
dc.subject	物種豐度模型	zh_TW
dc.subject	植群分類	zh_TW
dc.subject	ecosystem restoration	en
dc.subject	diversity	en
dc.subject	species abundance model	en
dc.subject	vegetation classification	en
dc.subject	degraded ecosystem	en
dc.title	復育物種選擇之研究 - 以蓮華池地區為例	zh_TW
dc.title	The Study of Species Selection in Restoration Plan: An Example of of Lienhuachih Region.	en
dc.type	Thesis
dc.date.schoolyear	101-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	陳子英,曾彥學
dc.subject.keyword	生態復育,退化生態系,多樣性,物種豐度模型,植群分類,	zh_TW
dc.subject.keyword	ecosystem restoration,degraded ecosystem,diversity,species abundance model,vegetation classification,	en
dc.relation.page	84
dc.rights.note	有償授權
dc.date.accepted	2013-08-13
dc.contributor.author-college	生物資源暨農學院	zh_TW
dc.contributor.author-dept	森林環境暨資源學研究所	zh_TW
顯示於系所單位：	森林環境暨資源學系

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