請用此 Handle URI 來引用此文件:
http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/32350
完整後設資料紀錄
DC 欄位 | 值 | 語言 |
---|---|---|
dc.contributor.advisor | 楊平世 | |
dc.contributor.author | Yi-Bin Fan | en |
dc.contributor.author | 范義彬 | zh_TW |
dc.date.accessioned | 2021-06-13T03:44:15Z | - |
dc.date.available | 2006-07-28 | |
dc.date.copyright | 2006-07-28 | |
dc.date.issued | 2006 | |
dc.date.submitted | 2006-07-26 | |
dc.identifier.citation | 方炎明。1996。植物生殖生態學。中國山東大學出版社。280頁。
王仁禮。1969。台灣產樟部諸科植物花粉粒形態之比較研究。林試所報告第175號。36頁。 王振灡、李銘華。1999。七種台灣楠木類木材之天然耐腐力探討。台灣林業科學14(1): 53-62。 安奎、鄭元春。1990。台灣產蜜源植物圖說(上)。台灣省立博物館。116頁。 安奎、鄭元春。1993。台灣產蜜源植物圖說(下)。台灣省立博物館。290頁。 邱少婷、黃俊霖。1993。花的前世今生。自然科學博物館。158頁。 林政行。1984。植物與昆蟲的共同演化。省立博物館。205頁。 林讚標、吳濟琛。1991。樟科種子儲藏與發芽試驗一、土肉桂與長葉木薑子。林業試驗所研究報告季刊 6(4): 339-344。 林讚標、陳清美。1993。大葉楠種子之不耐乾燥。林業試驗所研究報告季刊 8(2): 143-147。 林讚標、簡慶德。1995。六種楨楠屬植物種子之不耐旱特性。林業試驗所研究報告季刊 10(2): 217-226。 柳榗。1968。台灣植物群落之分類研究:I.台灣植物群系之分類。林試所報告第160號。20頁。 柳榗。1970。台灣植物群落之分類研究:III.台灣闊葉林及熱帶疏林群系。國科會報告第4號。36頁。 范義彬、呂勝由、彭立京。2005。一種深具發展潛力的植物-山胡椒【makauy】。台灣林業31(3): 61-62。 章樂民。1965。台灣熱帶降雨林生態之研究: (二)植被之研究。林試所報告第111號。18頁。 陳溫甫、羅育進。1977。中部地區木材產銷情形。台灣林業 3(7): 31-37。 陳國章、張乃航。1999。台灣樟科新木薑屬植物之訂正。台灣林業科學14(2): 141-163。 陳舜英、郭幸榮、Baskin J. M. 、Baskin C. C.、簡慶德。2006。高山新木薑種子的休眠與發芽。台灣林業科學21(1): 125-129。 欽俊德。1987。植物與昆蟲的關係。科學出版社。345頁。 黃增泉、陳淑華、陳世輝、郭長生、張惠珠、鄒稚華。1998。台灣空中孢粉誌。國立台灣大學植物學研究所。274頁。 楊世瑩。2005。SPSS統計分析實務。旗標出版社。455頁。 劉棠瑞、廖日京。1980。樹木學。台灣商務印書館。1252頁。 謝瑞忠。2003a。本樟樹葉與木材精油含量及其化學成分研究。台灣林業科學18(4): 317-327。 謝瑞忠。2003b。芳樟樹葉與木材精油含量及其化學成分研究。台灣林業科學18(4): 329-338。 韓韶華、謝長富、蔡來誠、莊雨奇。1980。台北地區的風媒植物與其花粉。中華微免13: 174-182。 簡慶德、楊佳如。1997。長葉木薑子種子成熟度影響種子的儲藏能力。台灣林業科學 12(3): 369-372。 簡慶德、莊身田、林讚標。1994。香楠種子儲藏性質的再探討。林業試驗所研究報告 9(3): 271-274。 簡慶德、楊正釧、林讚標。2004。香葉樹、大香葉樹、台灣雅楠、紅葉樹與山龍眼的儲藏性質。台灣林業科學 12(3): 119-131。 Aker, C. K. and D. Udovic. 1981. Oviposition and pollination behavior of the yucca moth. Tegeticula macula (Lepidoptera: Prodoxidae), and its relationship to the reproductive biology of Yucca whipplei (Agavaceae). Oecologia, 49: 96-101. Baker, H. G. 1976. “Mistake pollination” as a reproductive system with special reference to the Caricaceae. In: J. Burley and B. T. Styles (eds.), Tropical Trees: Variation, Breeding and Conservation. Academic Press, London. pp. 161-169. Barrett, S. C. H. 1988. The evolution, maintenance, and loss of self-incompatibility systems. In: J. Lovett Doust, and L. Lovett Doust (eds.) Plant Reproductive Ecology. Oxford University Press, New York. pp. 98-124. Barrett, S. C. H. 2003. Mating strategies in flowering plants: the outcrossing-selfing paradigm and beyond. Phil. Trans. R. Soc. Lond. B. 358: 991-1004. Bawa, K. S. 1980. Mimicry of male by female flowers and intrasexual competition for pollinators in Jacaratia dolichaula (D. Smith) Woodson (Caricaceae). Evolution, 34(3): 467-474. Bawa, K. S. and J. H. Beach. 1981. Evolution of sexual systems in flowering plants. Ann. Miss. Bot. Gard., 68: 254-274. Bawa, K. S. and C. J. Webb. 1984. Flower, fruit, and seed abortion in tropical forest trees: implications for the evolution of paternal and maternal reproductive patterns. Amer. J. Bot., 71: 736-751. Bertin, R. I. 1988. Paternity in plants. In: J. Lovett Doust and L. Lovett Doust (eds.) Plant Reproductive Ecology: Patterns and Strategies. Oxford Univ. Press, New York. pp. 30-59. Bertin, R. I. 1993. Incidence of monoecy and dichogamy in relation to self-fertilizaion in angiosperms. Am. J. Bot., 80: 557-560. Buchmann, S. L. 1983. Buzz pollination in angiosperms. In: C. E. Jones, and R. J. Little (eds.) Handbook of Experimental Pollination Biology. Van Nostrand, New York. pp. 73-113. Chang, C. E. 1976. Lauraceae. In: H. L. Li (ed.) Flora of Taiwan Vol.2. Epoch Publishing, Taipei. pp. 449-457. Charnov, E. L. 1982. The Theroy of Sex Allocation. Princeton Univ. Press, Princeton. 355 pp. Chen, I. H. 2000. Paternity exclusion and outcross rate of Machilus thunbergii Sieb. & Zucc. Using random amplified polymorphic DNA makers. NTU, Taipei. 57 pp. [in Chinese]. Chen, K. C. and F. J. Pan. 1997. New findings on the genus Neolitsea (Lauraceae) in Taiwan. Bull. Taiwan For. Res. Inst. New Series 12(2): 155-166. [in Chinese with English summary]. Cox, P. A. 1988. Monomorphic and dimorphic sexual strategies : a modular approach. In: J. Lovett Doust, and L. Lovett Doust (eds.) Plant Reproductive Ecology: Patterns and Strategies. Oxford University Press, New York. pp. 80-97. Crepet, W. L. and E. M. Friis. 1987. The evolution of insect pollination in angiosperms. . In: E. M. Friis, W. G. Chaloner, and P. R. Crane (eds.) The Origins of Angiosperms and Their Biological Consequences. Cambrige University Press, Cambridge. pp. 181-201. Cruden, R. W. 1977. Pollen-ovule ratios: a conservative indicator of breeding systems in plants. Evolution 31: 32-46. Douglas, E. S. and P. S. Soltis. 2003. The role of phylogenetics in comparative genetics. Plant Physiol. 132: 1790-1800. Eardley, C. D. and M. W. Mansell. 1994. Report on the natural occurrence of insect pollinators in an avocado orchard. Yearbook, South African Avocado Growers’ Association, 17: 117-118. Endress, P. K. 1997. Evolutionary biology of flowers: prospects for the next century. In: K. Iwatsuki, and P. H. Raven (eds.) Evolution and Diversification of Land Plants. Springer, New York. pp. 99-119. Frankel, R. and E. Galun. 1977. Pollination Mechanisms, Reproduction and Plant Breeding. Springer, Berlin. 281 pp. Friis, E. M. and W. L. Crepet. 1987. Time of appearance of floral features. In: E. M. Friis, W. G. Chaloner, and P. R. Crane (eds.) The Origins of Angiosperms and Their Biological Consequences. Cambridge University Press, Cambridge. pp. 145-179. Friis, E. M. and P. K. Endress. 1990. Origin and evolution of angiosperm flowers. Advances in Botanical Research 17: 99-162. Givnish, T. J. 1980. Ecological constraints on the evolution of breeding systems in seed plants: dioecy and dispersal in gymnosperms. Evolution 34: 959-972. Griffin, S. R., K. Mavraganis and C. G. Eckert. 2000. Experimental analysis of protogyny in Aquilegia canadensis (Ranunculaceae). Am. J. Bot., 87: 1246-1256. Gross, K. L. and J. D. Soule. 1981. Differences in biomass allocation to reproductive and vegetative structures of male and female plants of a dioecious, perennial herb, Sliene alba (Miller) Krause. Amer. J. Bot., 68: 801-807. Guitian, J. 1993. Why Prunus nahaleb (Rosaceae) produces more flowers then fruits. Amer. J. Bot., 80: 1305-1309. Harborne, J. B. 1993. Introduction to Ecological Biochemistry. Academic Press, London. 243 pp. Harder, L. D. and R. M. R. Barclay. 1994. The functional significance of poricidal anthers and buzz pollination: controlled pollen removal from Dodecatheon. Functional Ecology 8: 509-517. Henslow, G. 1888. The Origin of Floral Structures Through Insect and Other Agencies. Kegan, Paul & Trench, London. 349 pp. Heslop-Harrison, J. 1975. Incompatibility and the pollen-stigma interaction. Annu. Rev. Plant Physiol. 26: 403-425. Holtsford, T. P. 1985. Nonfruiting hermaphroditic flowers of Calochortus leichtlinii (Liliaceae): potential reproductive functions. Amer. J. Bot., 72: 1687-1694. House, S. M. 1989. Pollen movement to flowering canopies of pistil late individuals of three rain forest tree species in tropical Australia. Aust. J. Ecol 14: 77-94. House, S. M. 1993. Pollination success in a population of dioecious rain forest trees. Oecologia, 96 (4): 555-561. Ish, A.G. and D. Eisikowitch, 1993. The behavior of honeybee(Apis mellifera) visiting avocado (Persea Americana) flowers and their contribution. J. Apic. Res. 32 (3-4): 175-186. Iwanami, Y., T. Sasakuma, and Y. Yamada. 1988. Pollen: Illustration and Scanning Electronmicrographs. Kodansha Scientific Books, Tokyo. 198 pp. Johri, B. M. and I. K. Vasil, 1961. Physiology of pollen. Bot. Rev. 27: 325-381. Jolivet, P. 1998. Interrelationship between Insects and Plants. CRC Press, New York. 309 pp. Jones, C. E., and R. J. Little. 1983. Handbook of Experimental Pollination Biology. Van Nostrand Reinhold Company Inc., Yew York. 558 pp. Kapil, R. P. 1986. Pollination Biology. Inter-India Publications, New Delhi. 300 pp. Lee, S. J. 1984. Breeding mechanism of economic plants in Taiwan III. Breeding system of Machilus (Lauracee). CAPD Forestry Series 7: 20-30. [in Chinese with English summary]. Liao, J. C. 1988. The Taxonomic Revisions of the Family Lauraceae in Taiwan. National Taiwan University, Taipei. 185 pp. Liao, J. C. 1996. Lauraceae. In: T. C. Huang (ed.) Flora of Taiwan Vol. 2. Dept. Bot., Nat. Taiwan Univ, Taipei. pp. 484-496. Lloyd, D. G. and C. J. Webb. 1986. The avoidance of interference between the presentation of pollen and stigmas in angiosperms. 1. Dichogamy. NZJ. Bot., 24: 135-162. Lloyd, D. G. and S. C. Barrett. 1996. Floral Biology-Studies on Floral Evolution in Animal-pollinated Plants. International Thomson Publishing, Yew York. 410 pp. Maynard Smith, J. M. 1978. The evolution of sex. Cambridge University Press, Cambridge. 242 pp. Meagher, T. 1988. Sex determination in plants. In: J. Lovett Doust, and L. Lovett Doust (eds.) Plant Reproductive Ecology: Patterns and Strategies.Oxford Univ. Press, New York. pp. 125-138. Nikals, K. J. 1984. The motion of windborne pollen grains around conifer ovulate sones: implications on wind pollination. Amer. J. Bot., 71: 356-374. Pfahler, P. L. and H. F. Linskens. 1972. In vitro germination and pollen tube growth of maize ( Zea mays L.) pollen. VI. Combined effects of storage and the alleles at he waxy (wx), sugary (sul), and shrunken (sh2) loci. Theor. Appl. Genet. 42: 136- 140. Primack, R. B. 1985. Longevity of individual flowers. Ann. Rev. Ecol. Syst., 16: 15-37. Proctor, M., P. Yeo, and A. Lack. 1996. The Nature History of Pollination. Timber Press, Portland. 479 pp. Putwain, P. D. and J. L. Harper. 1972. Studies in the dynamics of plant population. V. Mechanisms governing sex ratio in Rumex acetosa and R. acetosella. J. Ecol., 60: 113-129. Risa, D. S. and P. O. Sarah. 2004. A phylogennetic analysis of pollination modern the evolution of dichogamy in angiosperms. Evol. Eco. Research. 6: 1183-1199. Schemske, D. W. 1980. Flora ecology and hummingbird pollination of Combretum farinosum in Costa Rica. Bio-tropica 12: 169-182. Schlessman, M. A. 1988. Gender diphasy (“sex choice”). In: J. Lovett Doust, and L. Lovett Doust (eds.) Plant Reproductive Ecology: Patterns and Strategies. Oxford University, New York. pp. 139-153. Schlessman, M. A., D. G. Lloyd and P. P. Lowry II. 1990. Evolution of sexual systems in New Caledonian Araliaceae. Mem. N. Y. Bot. Gard. 55:105-117. Sedgley, M. 1987. Flowering, pollination and fruit-set of avocado. Yearbook, South African Avocado Growers’ Association, 10: 42-43. Skutch, A. F. 1932. Observations on the flower behavior of the avocado in Panama. Torreya, 32: 85-94. Skutch, A. F. 1945. The behavior of the flowers of the aaguacatillo(Persea caerulea). Torreya, 45: 110-116. Smith, H. N. L. and F. C. Vasek. 1984. Pollen longevity and stigma pre-emption in Clarkia. Amer. J. Bot. 71: 1183-1191. Stephenson, A. G. 1980. Fruit set, herbivory, fruit reduction and the fruiting strategy of Catalpa speciosa (Bignoniaceae). Ecology 61: 57-64. Stout, A. B. 1923. A study of the cross-pollination of avocado in Southern California. Calif. Avoacdo Assoc. Rpt. 1922-23: 29-45. Stout, A. B. 1924. The flower mechanism of avocado with reference to pollination and the production of fruit. J. N. Y. Bot. Gard. 25: 1-7. Stout, A. B. 1927. The flower behavior of avocados. Mem. N. Y. Bot.Gard.7: 145-203. Stout, A. B. 1932. Sex in avocados and pollination. Calif. Avacado Assoc. Yearbook 1932: 172-173. Stout, A. B. 1933. The pollination of avocado. Florida Agr. Exp. Sta. Bull. 257: 1-44. Sun, G., D. L. Dilcher, S. Zheng and Z. Zhou. 1998. In search of the first: a Jurassic angiosperm, Archaefructus, from northeast China. Science 282: 1692-1695. Sutherland, S. and L. F. Delph. 1984. On the importance of male fitness in plants: patterns of fruit-set. Ecolody 65(4): 1093-1104. Sutherland, S. 1986. Floral sex ratios, fruit-set, and resource allocation in plants. Ecology, 67: 991-1001. Sutherland, S. 1987. Why nermanphrodite plants produce many more flowers, then fruits. Evolution, 41: 750-759. Thien, L. B. and P. Bernhardt. 1985. The pollination of Zygogonum (Winteraceae) by a moth, Sabatinca (Micropterigidae): an ancient association? Science 227: 540-543. Thomson, J. D. and R. C. Plowright. 1980. Pollen carryover nectar rewards and pollinator behavior with special reference to Diervilla lonnicera. Oecologia, 46: 68-74. Toit, A. P. 1994. Pollination of avocado, mangoes and litchis. Plant Protection News 35: 4-5. Trivers, R. L. and R. Hare. 1976. Haplodiploidy and the evolution of the social insects. Science, 191(4224): 250-263. Vithanage, V. 1990. The role of the European honeybee(Apis mellifera L.)in avocado pollination. J. Hortic.Sci. 65(1): 81-86. Wang, C. W. 1961. The forests of China. Maria Moors Cabot Foundation Publish. No. 5. Harvard Univ., Cambridge. 313 pp. Waller, D. M. 1988. Plant morphology and reproduction. In: J. Lovett Doust and L. Lovett Doust (eds.) Plant Reproductive Ecology:Patterns and Strategies. Oxford University Press, New York. pp. 203-277. Weberling, F. 1989. Morphology of Flowers and Inflorescences. Cambridge University Press, Cambridge. 405 pp. Whitehead, D. R. 1969. Wind pollination in the angiosperms: evolutionary and environmental consideration. Evolution 23: 28-35. Willemstein, S. C. 1987. An Evolutionary Basis for Pollination Ecology. Brill/Leiden University Press, Leiden. 425 pp. Willson, M. F. and K. P. Ruppel. 1984. Resource allocation and floral sex ratios in Zizania aquatica. Can. J. Bot., 62: 799-805. Wyatt, R. 1983. Pollinator-plant interactions and the evolution of breeding systems. In: L. Real (ed.) Pollination Biology. Academic Press, New York. pp. 51-95. | |
dc.identifier.uri | http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/32350 | - |
dc.description.abstract | 樟科植物(Lauraceae)是台灣森林中重要的組成樹種,本研究在瞭解樟樹(Cinnamomum camphora (Linn.) Presl.)、紅楠(Machilus thunbergii Sieb et Zucc)、山胡椒(Litsea cubeba (Lour.) Pers.)及長葉木薑子(Litsea acuminata (Blume) Kurata)開花生物學及其授粉生物學,並探討植物與訪花昆蟲間共同演化的關係。
樟樹(Cinnamomum camphora (Linn.) Presl.)為聚繖花序,兩性花,花期為3-4月;每朵花直徑5.52±0.58㎜,單花壽命6.45±1.41天;花粉數3170.7顆;花開放後夜間不閉合,花藥隨後開裂夜間不閉合;日夜皆有訪花昆蟲,共計5目23科65種昆蟲,以雙翅目(Diptera)11科33種最多,鱗翅目(Lepidoptera)5科15種次之,其他還有鞘翅目(Coleoptera)5科11種,半翅目(Hemiptera)2科3種,膜翅目(Hymenoptera)3科3種。訪花昆蟲即是其潛在可能的授粉昆蟲,但以雙翅目的蠅類為最重要;天然結實率1.23±2.89﹪。 紅楠(Machilus thunbergii Sieb et Zucc)為聚繖花序,兩性花,花期為2-3月;每朵花直徑10.32±0.73㎜,單花壽命4.24±1.08天;花粉數9273.6顆;花開放後閉合;日夜皆有訪花昆蟲,日間訪花昆蟲較多,訪花最頻繁的時段是09:00~15:00,紅楠訪花昆蟲共計5目21科34種昆蟲,以雙翅目11科22種最多,膜翅目5科9種、鱗翅目3科3種、鞘翅目1科3種、革翅目(Dermaptera)1科1種。其訪花昆蟲即是其潛在可能的授粉昆蟲,但以膜翅目的蜜蜂(Apis spp.)和雙翅目的蠅類為最重要;天然結實率5.98±11.11﹪。 山胡椒(Litsea cubeba (Lour.) Pers.)為繖形花序,單性花雌雄異株,花期為2-3月;雄花花序直徑9.20±0.82㎜,小花直徑3.73±0.77㎜,單花壽命13.03±4.52天,花粉數7786.8顆;雌花花序直徑8.11±0.85㎜,小花直徑2.28±0.35㎜,單花壽命15.68±4.90天。花開放後夜間不閉合,花藥隨後開裂夜間不閉合,日夜皆有訪花昆蟲。山胡椒訪花昆蟲有4目36科108種,以鞘翅目16科39種最多,鱗翅目7科33種次之,雙翅目7科24種、膜翅目6科12種。雄株訪花昆蟲共計4目33科77種昆蟲,以鞘翅目16科36種最多,鱗翅目6科16種次之,雙翅目6科15種、膜翅目5科10種;雌株共計4目16科44種昆蟲,以鱗翅目5科17種最多,鞘翅目 4科12種、雙翅目4科12種次之,膜翅目3科3種昆蟲。雌雄共同的訪花昆蟲計3目7科13種昆蟲,以鞘翅目4科9種最多,雙翅目2科3種次之,鱗翅目1科1種。往來於雌雄花之間者有鞘翅目的菊虎、金花蟲,雙翅目的食蚜蠅、鱗翅目的夜蛾和尺蛾,其主要授粉昆蟲;天然結實率29.76±19.90﹪。 蜜蜂(Apis spp.)不造訪樟樹花,且僅在山胡椒、長葉木薑子雄花上訪花,對山胡椒、長葉木薑子授粉並無貢獻,是盜粉者。 長葉木薑子(Litsea acuminata (Blume) Kurata)為繖形花序,單性花,雌雄異株,花期為6-7月;雄花花序直徑9.86±1.24㎜,花粉數14130顆;雌花花序直徑6.92±0.82㎜。花開放後夜間不閉合,花藥隨後開裂夜間不閉合,日夜皆有訪花昆蟲。長葉木薑子的訪花昆蟲有4目29科66種,以鱗翅目11科25種最多,雙翅目8科16種次之,膜翅目5科14種,鞘翅目5科11種。雄株訪花昆蟲共計4目26科59種昆蟲,以鱗翅目11科25種最多,雙翅目6科13種次之,膜翅目4科11種,鞘翅目5科10種;雌株訪花昆蟲共計4目9科16種,以膜翅目2科7種最多,雙翅目3科5種次之,鱗翅目3科3種、鞘翅目1科1種昆蟲。往來於雌雄花之間者有3目6科8種(2種蠅、3種蜂、2種蝶、1種蛾),以鱗翅目3科3種、膜翅目2科3種最多,雙翅目1科2種。是其主要授粉昆蟲;天然結實率22.88±23.17﹪。 總而言之,山胡椒和長葉木薑子(單性花雌雄異株)以結實率來說,較樟樹和紅楠(兩性花雌雄同株)的繁殖為成功。雖然山胡椒和長葉木薑子(單性花雌雄異株)的授粉模式較樟樹和紅楠(兩性花雌雄同株)單純。 | zh_TW |
dc.description.abstract | The family Lauraceae contains the most dominant species in Taiwan’s natural hardwood forest and is considered one of the most important families in Taiwan. This study was focused on the florescence and pollinating biology of four widely distributed species of Laurel family, Cinamomum camphora (Linn.) Presl., Machilus thunbergii Sieb et Zucc, Litsea cubeba (Lour.) Pers. and Litsea acuminata (Blume) Kurata, in Taiwan’s broadleaf forests and the co-evolution relationship between those plants and related insects.
Cinamomum camphora (Linn.) Presl. is characterized by inflorescence cryme and hermaphroditism. The average flower size, longevity and average number of pollen grains were 5.52±0.58mm, 6.45±1.41 days and 3170.7 grains respectively. The blooming season was from March to April and flowers and stamens are open no matter day and night when blooming. Totally 65 insect species of 23 families of 5 orders were observed. Their taxonomic composition were: Diptera (11 families, 33 species), Lepidoptera (5 families, 15 species), Coleoptera (5 families, 11 species), Hemiptera (2 families, 3 species) and Hymenoptera (3 families, 3 species). Insect visitors to the blossoms were the potential pollinators and flies are the most important ones. Natural fruit-set rate was 1.23±2.89﹪. Machilus thunbergii Sieb et Zucc is characterized by inflorescence cryme and hermaphroditism. The size of flower, longevity of individual flower and the average number of pollen grains is 10.32±0.73 mm, 4.24± 1.08 days and 9273.6 grains respectively. The blooming season is in the spring from February to March, flowers and stamens will close after opening, and insects visit the blossoms day and night, especially during 09:00~15:00. There were totally 34 species insects of 21 families from 5 orders were recorded to visit flowers of M. thunbergii. Their taxonomic composition were: Diptera (11 families, 22 species), Lepidoptera (3 families, 3 species), Coleoptera(1 families, 1 species), and Dermaptera (1 families, 1 species). Insect visitors were the potential pollinators and honeybees (Apis spp.) and flies were the most important ones. Natural fruit-set rate was 5.98±11.11﹪. Litsea cubeba (Lour.) Pers. is characterized by inflorescence umbel and dioecism. Blooming season is from February to March. Male inflorescence diameter was 9.20±0.82 mm and small flower diameter was 3.73±0.77mm; the longevity of individual flower were 13.04±4.52 days and the number of pollen grains was 7786.8. While size of female inflorescence diameter, small flower diameter and longevity of individual flower were 8.11±0.85 mm, 2.28±0.35 mm and 15.68±4.90 days respectively. Flower and stamens are open all the day when blooming. Their insect visitors include 108 species of 36 families from 4 orders. Their taxonomic composition were: Coleoptera (16 families, 39 species), Lepidoptera (6 families, 33 species), Diptera (7 families, 24 species) and Hymenoptera (6 families, 12 species). 77 species of 33 families from 4 orders have been observed visiting male flowers of L. cubeba. They were: Coleoptera (16 families, 36 species), Lepidoptera (5 families, 16 species), Diptera (6 families, 15 species) and Hymenoptera (5 families, 10 species). There were 44 species of 16 families from 4 orders visited the female flowers of L. cubeba. They were: Lepidoptera (5 families, 17 species), Coleoptera (4 families, 12 species), Diptera (4 families, 12 species) and Hymenoptera (3 families, 3 species). The major pollinating insects flying between male and female flowers include Cantharidae and Chrysomelidae (Coleoptera), Syrphidae (Diptera), Noctuidae and Geometridae (Lepidoptera). Natural fruit-set rate was 29.76±19.90﹪. In addition, honeybees (Apis spp.) have been verified not visiting flowers of C. camphora and female flowers of L. cubeba and L. acuminata. Therefore they are pollen robbers rather than pollinators. Litsea acuminata (Blume) Kurata is characterized by inflorescence umbel and dioecism. It will bloom in June and July. The average size of male and female inflorescence diameter is 9.86±1.24 mm and 6.92±0.82 mm respectively. It has 14130 grains of pollen in average. Flowers and stamens are also open in both daytime and nighttime when blooming. Their insect visitors include 66 species of 29 families from 4 orders. Their taxonomic composition were: Lepidoptera (11 families, 25 species), Diptera (8 families, 16 species) , Hymenoptera (5 families, 14 species) and Coleoptera (5 families, 11 species). There were 59 species of 33 families from 4 orders visited male flowers of L. acuminata. They were: Lepidoptera (11 families, 25 species), Diptera (6 families, 13 species). Hymenoptera (4 families, 11 species) and Coleoptera (5 families, 10 species). There were 16 species of 9 families from 4 orders visited the female flowers of L. acuminata. They were: Lepidoptera (3 families, 3 species), Coleoptera (1 families, 1 species) and Diptera (3 families, 5 species). There were 8 species of 6 families from 3 orders visiting both male and female flowers, major pollinating insects were: Lepidoptera (2 families, 3 species), Hymenoptera (2 families, 3 species) and Diptera (1 families, 2 species). Natural fruit-set rate was 29.76±19.90﹪. In conclusion, the reproduction of L. cubeba and L. acuminata (dioecism) is much more successful than C. camphora and M. thunbergii’s(hermaphroditism) in the fruit-set even though the pollination mode of L. cubeba and L. acuminata (dioecism) is simplier than C. camphora and M. thunbergii’s(hermaphroditism). | en |
dc.description.provenance | Made available in DSpace on 2021-06-13T03:44:15Z (GMT). No. of bitstreams: 1 ntu-95-F85624105-1.pdf: 1189356 bytes, checksum: ade63a5a7dc621b5ab5d4f191490fad0 (MD5) Previous issue date: 2006 | en |
dc.description.tableofcontents | 中文摘要
英文摘要 目錄…………………………………………………………………….vii 表次…………………………………………………………………….ix 圖次…………………………………………………………………….xi 壹、緒言………………………………………………………………..1 貳、樟科植物之花部形態研究………………………………………..7 一、 前言…………………………………………………………....7 二、 材料與方法………………………………………………..…..8 1. 花形態的觀察………………………………………………………….…..8 2. 花粉形態的觀察………………………………………………….…….….8 3. 花粉數量的調查……………………………………………….…………..8 三、 結果………………………………………….…………………8 四、 討論……………………………………………………………11 參、樟科植物之物候、雌雄比率及結實率研究…………………….14 一、前言……………………………………………………………14 二、材料與方法……………………………………………………16 1. 樟科花朵開放時間調查……………………………………………….…16 2. 花壽命……………………………………………..……………16 3. 雌雄比率……………………………………………………………….…16 4. 樟樹人工授粉的調查研究……………………………………….. 16 5.結實率……………………….…………………………………………….17 三、結果…………………………………………………………….18 四、討論…………………………………………………………….20 肆、樟科植物之授粉昆蟲研究………………………………………..23 一、前言…………………………………………………………….23 二、材料與方法…………………………………………………….24 1.樟科訪花昆蟲調查…………………………………………………….….24 2.樟科訪花昆蟲動態調查…………………………………………………..24 3.訪花昆蟲身軀花粉調查…………………………………………...25 三、結果…………………………………………………………….25 四、討論…………………………………………………………….30 伍、綜合討論…………………………………………………………..34 陸、結論………………………………………………………………..39 柒、引用文獻…………………………………………………………..41 捌、誌謝………………………………………………………………..50 玖、附錄………………………………………………………………..51 一、 表………………………………………………………………..51 二、 圗………………………………………………………………..61 三、 名錄……………………………………………………………..77 表次 表一、樟樹、紅楠、山胡椒與長葉木薑子花朵形態表。……………………….51 Table 1. Flower morphology of Cinnamomum camphora, Machilus thunbergii, Litsea cubeba and Litsea acuminata. 表二、樟樹、紅楠、山胡椒與長葉木薑子花粉形態表。………………………. 51 Table 2. Pollen morphology of Cinnamomum camphora, Machilus thunbergii, Litsea cubeba and Litsea acuminata. 表三、樟樹與山胡椒花藥開放比例調查表。……………………………………. 52 Table 3. The anther dehiscence time of Cinnamomum camphora and male Litsea cubeba. 表四、山胡椒雌雄比例調查表。…………………………….…………………….52 Table 4. Number of female and male individuals of Litsea cubeba diference localities. 表五、樟樹人工授粉調查表。……………………………………………………..52 Table 5. Fruit-set after artificial pollination survey of Cinnamomum camphora flowers. 表六、樟樹、紅楠、山胡椒與長葉木薑子天然結實率調查表。.……………….53 Table 6. Spontaneous fruit-set of Cinnamomum camphora, Machilus thunbergii, Litsea cubeba and Litsea acuminata. 表七、4種樟科植物結實率變異數分析表。…………………………..………….53 Table 7. The analysis of variance of fruit-sets of 4 Lauarceae plants. 表八、4種樟科植物結實率相關分析表。………………………………………...54 Table 8. The correlations analysis of fruit-sets of 4 Lauraceae plants. 表九. 樟樹訪花昆蟲身體花粉調查表。……………………………………..…….55 Table 9. Pollen counts from the surface of insectscollected from Cinnamomum camphora flowers. 表十、紅楠訪花昆蟲身體花粉調查表。………………………………………….56 Table 10. Pollen counts from the surface of insects collected from Machilus thunbergii flowers. 表十一、山胡椒訪花昆蟲身體花粉調查表。…………………………………….57 Table 11. Pollen counts from the surface of insects collected from Litsea cubeba flowers. 表十二、長葉木薑子訪花昆蟲身體花粉調查表。……………………………….58 Table 12. Pollen counts from the surface of insects collected from Litsea acuminata flowers. 表十三、樟花訪花昆蟲攜帶花粉種類及數量調查表。………………………….59 Table 13. Surveys on the pollen' variety and count from Cinnamomum camphora flower visitors. 表十四、山胡椒訪花昆蟲攜帶花粉種類及數量調查表。……………………….60 Table 14. Surveys on the pollen' variety and count from Litsea cubeba flower visitors. 圖次 圖一、樟科的花朵:A. 樟樹、B. 紅楠、C. 山胡椒雄花、D. 山胡椒雌花、E. 長葉木薑子雄花、F. 長葉木薑子雌花。…………………………………………..61 Fig.1. The flower of Lauraceae. A. C. camphora. B. M. thunbergii. C. L. cubeba♂. D. L. cubeba♀. E. L. acuminata♂. F. L. acuminata♀. 圖二、花粉電子顯微照片:A.樟樹、B.紅楠、C.山胡椒、D.長葉木薑子。…….62 Fig.2.The pollen SEM photomicrographs: A. C. camphora. B. M. thunbergii. C. L. cubeba. D. L. acuminata. 圖三、4種樟科植物結實率分佈圖。……………………………………………….63 Fig. 3.The distribution of fruit-sets of 4 Lauaceae plants. 圖四、樟樹訪花昆蟲比例圖。………………………………………………….…...64 Fig. 4. The proportion of flower visitors of C. camphora. 圖五、紅楠訪花昆蟲比例圖。……………………………………………….…..….64 Fig. 5. The proportion of flower visitors of M. thunbergii. 圖六、山胡椒雄株訪花昆蟲比例圖。……………………………………….……...65 Fig. 6.The proportion of flower visitors of male L. cubeba. 圖七、山胡椒雌株訪花昆蟲比例圖。………………………………………..…….65 Fig. 7. The proportion of flower visitors of female L. cubeba. 圖八、長葉木薑子雄株訪花昆蟲比例圖。………………………………….……..66 Fig. 8. The proportion of flower visitors of male L. acuminata. 圖九、長葉木薑子雌株訪花昆蟲比例圖。………………………………..……….66 Fig. 9. The proportion of flower visitors of female L. acuminata. 圖十、樟樹訪花昆蟲動態圖(花盛-末期)。………………………………………67 Fig.10. Flower visitors’ dynamic of C. camphora(flower rich-last period). 圖十一、樟樹訪花昆蟲動態圖(花初-盛期)。………………………………..….67 Fig.11. Flower visitors’ dynamic of C. camphora(flower early- rich period). 圖十二、紅楠訪花昆蟲動態圖。………………………………………………..….68 Fig.12. Flower visitors’ dynamic of M. thunbergii. 圖十三、山胡椒雄株訪花昆蟲動態圖(蓮華池2001.03.06)。…………………..68 Fig.13. Flower visitors’ dynamic of male L. cubeba(Lianhuachi, 2001.03.06). 圖十四、山胡椒雌株訪花昆蟲動態圖(蓮華池2001.03.06)。…………………..69 Fig.14. Flower visitors’ dynamic of female L. cubeba(Lianhuachi, 2001.03.06). 圖十五、山胡椒雄株訪花昆蟲動態圖(烏來2001.03.12)。……………………..69 Fig.15. Flower visitors’ dynamic of male L. cubeba(Wulai, 2001.03.12). 圖十六、山胡椒雌株訪花昆蟲動態圖(烏來2001.03.12)。……………………..70 Fig.16. Flower visitors’ dynamic of female L. cubeba(Wulai, 2001.03.12). 圖十七、長葉木薑子雄株訪花昆蟲動態圖。……………………………………..70 Fig.17. Flower visitors’ dynamic of male L. acuminata. 圖十八、長葉木薑子雌株訪花昆蟲動態圖。……………………………………..71 Fig.18. Flower visitors’ dynamic of female L. acuminata. 圖十九、樟樹訪花昆蟲。…………………………………………………………..72 Fig. 19. The flower visitors of C. camphora. 圖二十、紅楠訪花昆蟲。…………………………………………………………..73 Fig. 20. The flower visitors of male L. cubeba. 圖二十一、山胡椒雄株訪花昆蟲。………………………………………………..74 Fig. 21. The flower visitors of male L. cubeba. 圖二十二、山胡椒雌株訪花昆蟲。…………………………………………….....75 Fig. 22. The flower visitors of female L. cubeba. 圖二十三、長葉木薑子訪花昆蟲。……………………………………………….76 Fig. 23. The flower visitors of L. acuminata. 附錄 附錄一、樟樹訪花昆蟲名錄。 Appendix 1. The fauna of C. camphora’ flower visitors. 附錄二、紅楠訪花昆蟲名錄。 Appendix 2. The fauna of M. thunbergii’ flower visitors. 附錄三、山胡椒訪花昆蟲名錄。 Appendix 3. The fauna of L. cubeba’ flower visitors. 附錄四、長葉木薑子訪花昆蟲名錄。 Appendix 4. The fauna of L. acuminata’ flower visitors. | |
dc.language.iso | zh-TW | |
dc.title | 台灣樟科植物開花授粉生物學之研究 | zh_TW |
dc.title | The Floral and Pollination Biology of Lauraceae in Taiwan | en |
dc.type | Thesis | |
dc.date.schoolyear | 94-2 | |
dc.description.degree | 博士 | |
dc.contributor.oralexamcommittee | 潘富俊,何鎧光,徐堉峰,陳建志 | |
dc.subject.keyword | 樟樹,紅楠,山胡椒,長葉木薑子,樟科,開花生物學,授粉生物學,共同演化, | zh_TW |
dc.subject.keyword | Cinnamomum camphora,Machilus thunbergii,Litsea cubeba,Litsea acuminata,Lauraceae,floral biology,pollination biology,coevolution, | en |
dc.relation.page | 76 | |
dc.rights.note | 有償授權 | |
dc.date.accepted | 2006-07-26 | |
dc.contributor.author-college | 生物資源暨農學院 | zh_TW |
dc.contributor.author-dept | 昆蟲學研究所 | zh_TW |
顯示於系所單位: | 昆蟲學系 |
文件中的檔案:
檔案 | 大小 | 格式 | |
---|---|---|---|
ntu-95-1.pdf 目前未授權公開取用 | 1.16 MB | Adobe PDF |
系統中的文件,除了特別指名其著作權條款之外,均受到著作權保護,並且保留所有的權利。