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完整後設資料紀錄
DC 欄位 | 值 | 語言 |
---|---|---|
dc.contributor.advisor | 吳文哲(Wen-Jer Wu) | |
dc.contributor.author | Mu-Hsin Yen | en |
dc.contributor.author | 顏睦歆 | zh_TW |
dc.date.accessioned | 2021-06-13T00:17:53Z | - |
dc.date.available | 2008-07-30 | |
dc.date.copyright | 2007-07-30 | |
dc.date.issued | 2007 | |
dc.date.submitted | 2007-07-27 | |
dc.identifier.citation | Amundson, R., A. T. Austin, E. A. G. Schuur, K. Yoo, V. Matzek, C. Kendall, A. Uebersax, D. Brenner, and W. T. Baisden. 2003. Global patterns of the isotopic composition of soil and plant nitrogen. Glob. Biogeochem. Cycles 17: 31-1-31-5.
Barnes, B. V., D. R. Zak, S. R. Denton, and S. H. Spurr. 1998. Forest Ecology. 4th ed. John Wiley & Sons, Inc., New York. 774 pp. Benzing, D. H. 1990. Vascular Epiphytes: General Biology and Related Biota. Cambridge University, Cambridge, UK. 354 pp. Cabana, G., and J. B. Rasmussen. 1994. Modeling food-chain structure and contaminant bioaccumulation using stable nitrogen isotopes. Nature 372: 255-257. Cai, Z. Q., and F. Bongers. 2007. Contrasting nitrogen and phosphorus resorption efficiencies in trees and lianas from a tropical montane rain forest in Xishuangbanna, south-west China. J. Trop. Ecol. 23: 115-118. Chapin, F. S., and R. A. Kedrowski. 1983. Seasonal-changes in nitrogen and phosphorus fractions and autumn retranslocation in evergreen and deciduous taiga trees. Ecology 64: 376-391. Chapin, F. S., and L. Moilanen. 1991. Nutritional controls over nitrogen and phosphorus resorption from Alaskan birch leaves. Ecology 72: 709-715. Christenson, L. M., G. M. Lovett, M. J. Mitchell, and P. M. Groffman. 2002. The fate of nitrogen in gypsy moth frass deposited to an oak forest floor. Oecologia 131: 444-452. Coll, M., and M. Guershon. 2002. Omnivory in terrestrial arthropods: Mixing plant and prey diets. Annu. Rev. Entomol. 47: 267-297. Davidson, D. W., S. C. Cook, R. R. Snelling, and T. H. Chua. 2003. Explaining the abundance of ants in lowland tropical rainforest canopies. Science 300: 969-972. DeNiro, M. J., and S. Epstein. 1978. Influence of diet on the distribution of carbon isotopes in animals. Geochim. Cosmochim. Acta 42: 495-506. DeNiro, M. J., and S. Epstein. 1981. Influence of diet on the distribution of nitrogen isotopes in animals. Geochim. Cosmochim. Acta 45: 341-351. Eggers, T., and T. H. Jones. 2000. You are what you eat ... or are you? Trends Ecol. Evol. 15: 265-266. Ellwood, M. D. F., and W. A. Foster. 2004. Doubling the estimate of invertebrate biomass in a rainforest canopy. Nature 429: 549-551. Ellwood, M. D. F., D. T. Jones, and W. A. Foster. 2002. Canopy ferns in lowland dipterocarp forest support a prolific abundance of ants, termites, and other invertebrates. Biotropica 34: 575-583. Erskine, P. D., D. M. Bergstrom, S. Schmidt, G. R. Stewart, C. E. Tweedie, and J. D. Shaw. 1998. Subantarctic Macquarie Island - a model ecosystem for studying animal-derived nitrogen sources using 15N natural abundance. Oecologia 117: 187-193. Evans, R. D. 2001. Physiological mechanisms influencing plant nitrogen isotope composition. Trends Plant Sci. 6: 121-126. Fábián, M. 1998. The effects of different methods of preservation on the 15N concentration in Folsomia candida (Collembola). Appl. Soil Ecol. 9:101-104. Frost, C. J., and M. D. Hunter. 2007. Recycling of nitrogen in herbivore feces: plant recovery, herbivore assimilation, soil retention, and leaching losses. Oecologia 151: 42-53. Gannes, L. Z., D. M. O'Brien, and C. M. del Rio. 1997. Stable isotopes in animal ecology: Assumptions, caveats, and a call for more laboratory experiments. Ecology 78: 1271-1276. Gannes, L. Z., C. M. del Rio, and P. Koch. 1998. Natural abundance variations in stable isotopes and their potential uses in animal physiological ecology. Comp. Biochem. Physiol. 119A: 725-737. Gratton, C., and R. F. Denno. 2006. Arthropod food web restoration following removal of an invasive wetland plant. Ecol. Appl. 16: 622-631. Hietz, P., and W. Wanek. 2003. Size-dependent variation of carbon and nitrogen isotope abundances in epiphytic bromeliads. Plant Biol. 5: 137-142. Hietz, P., W. Wanek, R. Wania, and N. M. Nadkarni. 2002. Nitrogen-15 natural abundance in a montane cloud forest canopy as an indicator of nitrogen cycling and epiphyte nutrition. Oecologia 131: 350-355. Höfstede, R. G. M., J. H. D. Wolf, and D. H. Benzing. 1993. Epiphytic biomass and nutrient status of a Colombian upper montane rain forest. Selbyana 14: 37-45. Högberg, P. 1997. Transley Review No. 95: 15N natural abundance in soil-plant systems. New Phytol. 137: 179-203. Hood-Nowotny, R., and B. G. J. Knols. 2007. Stable isotope methods in biological and ecological studies of arthropods. Entomol. Exp. Appl. 124: 3-16. Hsu, C. C. 1998. Epiphyte biomass and nutrient capital of Machilus-Castonopsis forest in the Fushan Experimental Forest. Master thesis, Graduate Institute of Botany, National Taiwan University, Taipei. 67 pp. (in Chinese) Hsu, C. C., F. W. Horng, and C. M. Kuo. 2002. Epiphyte biomass and nutrient capital of a moist subtropical forest in north-eastern Taiwan. J. Trop. Ecol. 18: 659-670. Hsu, C. C., T. C. Lin, W. L. Chiou, S. H. Lin, K. C. Lin, and C. E. Martin. 2006. Canopy CO2 concentrations and Crassulacean acid metabolism in Hoya carnosa in a subtropical rain forest in Taiwan: consideration of CO2 avallability and the evolution of CAM in epiphytes. Photosynthetica 44: 130-135. Huang, J. J., X. H. Wang, and E. R. Yan. 2007. Leaf nutrient concentration, nutrient resorption and litter decomposition in an evergreen broad-leaved forest in eastern China. For. Ecol. Manage. 239: 150-158. Huhta, V. 2007. The role of soil fauna in ecosystems: A historical review. Pedobiologia 50: 489-495. Jiang, Y. Y. 1996. Study on dependent plants at Guandaushi forest ecosystem. Master thesis, Graduate Institute of Botany, National Chung-Hsing University, Taichung. 81 pp. (in Chinese) Karasawa, S., and N. Hijii. 2006. Effects of distribution and structural traits of bird's nest ferns (Asplenium nidus) on oribatid (Acari: Oribatida) communities in a subtropical Japanese forest. J. Trop. Ecol. 22: 213-222. Kitayama, K., and K. Iwamoto. 2001. Patterns of natural 15N abundance in the leaf-to-soil continuum of tropical rain forests differing in N availability on Mount Kinabalu, Borneo. Plant Soil 229: 203-212. Lancaster, J., D. C. Bradley, A. Hogan, and S. Waldron. 2005. Intraguild omnivory in predatory stream insects. J. Anim. Ecol. 74: 619-629. Lin, K. C., N. H. Chang, C. P. Wang, and C. P. Liu. 2002. Green foliage decomposition and its nitrogen dynamics of 4 tree species of the Fushan Forest. Taiwan J. For. Sci. 17: 75-85. Martin, C. E., T. C. Lin, C. C. Hsu, S. H. Lin, K. C. Lin, Y. J. Hsia, and W. L. Chiou. 2004. Ecophysiology and plant size in a tropical epiphytic fern, Asplenium nidus, in Taiwan. Int. J. Plant Sci. 165: 65-72. McKechnie, A. E. 2004. Stable isotopes: powerful new tools for animal ecologists. S. Afr. J. Sci. 100: 131-134. McNabb, D. M., J. Halaj, and D. H. Wise. 2001. Inferring trophic positions of generalist predators and their linkage to the detrital food web in agroecosystems: a stable isotope analysis. Pedobiologia 45: 289-297. Minagawa, M., and E. Wada. 1984. Stepwise enrichment of 15N along food chains: further evidence and the relation between δ15N and animal age. Geochim. Cosmochim. Acta 48: 1135-1140. Mooney, K. A., and C. V. Tillberg. 2005. Temporal and spatial variation to ant omnivory in pine forests. Ecology 86: 1225-1235. Nadkarni, N. M. 1984. Epiphyte biomass and nutrient capital of a neotropical elfin forest. Biotropica 16: 249-256. Nadkarni, N. M., and J. T. Longino. 1990. Invertebrates in canopy and ground organic matter in a neotropical montane forest, Costa Rica. Biotropica 22: 286-289. Nadkarni, N. M., D. Schaefer, T. J. Matelson, and R. Solano. 2004. Biomass and nutrient pools of canopy and terrestrial components in a primary and a secondary montane cloud forest, Costa Rica. For. Ecol. Manage. 198: 223-236. O'Reilly, C. M., R. E. Hecky, A. S. Cohen, and P. D. Plisnier. 2002. Interpreting stable isotopes in food webs: recognizing the role of time averaging at different trophic levels. Limnol. Oceanogr. 47: 306-309. Park, H. H., and J. H. Lee. 2006. Arthropod trophic relationships in a temperate rice ecosystem: A stable isotope analysis with δ13C and δ15N. Environ. Entomol. 35: 684-693. Pentecost, A. 1998. Some observations on the biomass and distribution of cryptogamic epiphytes in the upper montane forest of the Rwenzori Mountains, Uganda. Global Ecol. Biogeog. Letters 7: 273-284. Ponsard, S., and M. Amlou. 1999. Effects of several preservation methods on the isotopic content of Drosophila samples. C. R. Acad. Sci., Ser. 3, Sci. Vie 322: 35-41. Ponsard, S., and R. Arditi. 2000. What can stable isotopes (15N and 13C) tell about the food web of soil macro-invertebrates? Ecology 81: 852-864. Ponsard, S., and R. Arditi. 2001. Detecting omnivory with δ15N - Comment from Ponsard & Arditi. Trends Ecol. Evol. 16: 20-21. Post, D. M., M. L. Pace, and N. G. Hairston. 2000. Ecosystem size determines food-chain length in lakes. Nature 405: 1047-1049. Reich, A., J. J. Ewel, N. M. Nadkarni, T. Dawson, and R. D. Evans. 2003. Nitrogen isotope ratios shift with plant size in tropical bromeliads.Oecologia 137: 587-590. Reynolds, B. C., and M. D. Hunter. 2001. Responses of soil respiration, soil nutrients, and litter decomposition to inputs from canopy herbivores. Soil Biol. Biochem. 33: 1641-1652. Robinson, D. 2001. δ15N as an intergrator of the nitrogen cycle. Trends Ecol. Evol. 16: 153-162. Sanzone, D. M., J. L. Meyer, E. Marti, E. P. Gardiner, J. L. Tank, and N. B. Grimm. 2003. Carbon and nitrogen transfer from a desert stream to riparian predators. Oecologia 134: 238-250. Scheu, S. 2002. The soil food web: structure and perspectives. Eur. J. Soil Biol. 38: 11-20. Scheu, S., and M. Falca. 2000. The soil food web of two beech forests (Fagus sylvatica) of contrasting humus type: stable isotope analysis of a macro- and mesofauna-dominated community. Oecologia 123: 285-296. Schmidt, O., C. M. Scrimgeour, and L. L. Handley. 1997. Natural abundance of 15N and 13C in earthworms from a wheat and a wheat-clover field. Soil Biol. Biochem. 29: 1301-1308. Schmidt, O., J. P. Curry, J. Dyckmans, E. Rota, and C. M. Scrimgeour. 2004. Dual stable isotope analysis (δ13C and δ15N) of soil invertebrates and their food sources. Pedobiologia 48: 171-180. Schuur, E. A. G., and P. A. Matson. 2001. Net primary productivity and nutrient cycling across a mesic to wet precipitation gradient in Hawaiian montane forest. Oecologia 128: 431-442. Sergeeva, T. K., L. B. Kholopova, N. T. Ten, and N. S. Thu. 1989. Animal populace and properties of perched soils of the tropical epiphyteAsplenium nidus L. Sov. J. Ecol. 20: 284-293. Solano, P. J., and A. Dejean. 2004. Ant-fed plants: comparison between three geophytic myrmecophytes. Biol. J. Linn. Soc. 83: 433-439. Stewart, G. R., S. Schmidt, L. L. Handley, M. H. Turnbull, P. D. Erskine, and C. A. Joly. 1995. 15N natural abundance of vascular rainforest epiphytes: implications for nitrogen source and acquisition. Plant Cell Environ. 18: 85-90. Swift, M. J., O. W. Heal, and J. M. Anderson. 1979. Decomposition in Terrestrial Ecosystems. Blackwell Scientific Publication, Oxford. 372 pp. Tanner, E. V. J. 1977. Four montane rain forests of Jamaica: a quantitative characterization of the floristics, and soils and the foliar mineral levels, and a discussion of the interrelation. J. Ecol. 65: 883-918. Tayasu, I., F. Hyodo, and T. Abe. 2002a. Caste-specific N and C isotope ratios in fungus-growing termites with special reference to uric acid preservation and their nutritional interpretation. Ecol. Entomol. 27: 355-361. Tayasu, I., T. Nakamura, H. Oda, F. Hyodo, Y. Takematsu, and T. Abe. 2002b. Termite ecology in a dry evergreen forest in Thailand in terms of stable (δ13C and δ15N) and radio (14C, 137Cs and 210Pb) isotopes. Ecol. Res. 17: 195-206. Tillberg, C. V., D. P. McCarthy, A. G. Dolezal, and A. V. Suarez. 2006. Measuring the trophic ecology of ants using stable isotopes. Insectes Sociaux 53: 65-69. Treseder, K. K., D. W. Davidson, and J. R. Ehleringer. 1995. Absorption of ant-provided carbon dioxide and nitrogen by a tropical epiphyte. Nature 375: 137-139. Tsai, P. H. 2005. The phenology of Asplenium antiquum Makino in the Fushan Experimental Forest. Master thesis, School of Forestry and Resource Conservation, National Taiwan University, Taipei. 53 pp. (in Chinese) Uetz, G. W., J. Halaj, and A. B. Cady. 1999. Guild structure of spiders in major crops. J. Arachnol. 27: 270-280. Wang, C. P., and K. C. Lin. 2003. Variation of 15N natural abundance in leaves and soils of two natural Lauro-Fagaceae forest in Taiwan. Taiwan J. For. Sci. 18: 153-157. Wang, L. J. 1994. Hydrogeochemical cycle and storm solute transport in the subtropical Fushan experimental forest, NE Taiwan. Doctor of Philosophy thesis, College of Forest Resources, University of Washington, Seattle. 129 pp. Wania, R., P. Hietz, and W. Wanek. 2002. Natural 15N abundance of epiphytes depends on the position within the forest canopy: source signals and isotope fractionation. Plant Cell Environ. 25: 581-589. Yang, J. T., M. Y. Chen, and Y. Y. Jiang. 2001a. Biodiversity of the invertebrate community in epiphytic substrates of Guandaushi forest ecosystem, central Taiwan. Formosan Entomol. 21: 99-117. (in Chinese) Yang, J. T., M. Y. Chen, and Y. Y. Jiang. 2001b. Biodiversity of ant-guest community in the epiphytic substrates of Guandaushi forest ecosystem, central Taiwan. Quart. J. For. Res. Taiwan 23: 31-44. (in Chinese) Yanoviak, S. P., H. Walker, and N. M. Nadkarni. 2004. Arthropod assemblages in vegetative vs. humic portions of epiphyte mats in a neotropical cloud forest. Pedobiologia 48: 51-58. Yanoviak, S. P., N. M. Nadkarni, and R. Solano. 2007. Arthropod assemblages in epiphyte mats of Costa Rican cloud forests. Biotropica 39: 202-210. Yen, C. Y. 2004. Arthropod community structure in epiphyte substrates of Guan-dau-shi forest ecosystem. Master thesis, Departement of Entomology, National Chung-Hsing University, Taichung. 37 pp. (in Chinese) Zanden, M. J. V., B. J. Shuter, N. Lester, and J. B. Rasmussen. 1999. Patterns of food chain length in lakes: A stable isotope study. Am. Nat. 154: 406-416. | |
dc.identifier.uri | http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/28693 | - |
dc.description.abstract | 本研究於福山試驗林,採集共13株台灣山蘇花 (Asplenium nidus L.),分離出基質動物相,以探討台灣山蘇花大小對其基質無脊椎動物數量之影響,其後測量植體及動物體樣品之乾重與穩定同位素天然含量 (δ13C ‰、δ15N ‰),來探討山蘇利用動物性氮源之可能,並藉以分析基質動物相之食性層級。平均葉長大於60 cm 以上的台灣山蘇花因基質乾重及植體總乾重呈現指數成長而大量累積,生長於其中的無脊椎動物生物量總乾重則隨之呈對數型成長,對數轉換之動物體總生物量與山蘇總乾重呈良好之線性廻歸 (R2 = 0.7,P < 0.01),由此可知植體生物量的累積與動物體之增長形式 (速率) 不同,因而造成單位基質重之動物體乾重百分比在平均葉長40~60 cm 的山蘇 (中型山蘇) 較高 (0.3~2.2%),而小型山蘇 (平均葉長 < 30 cm) 及大型山蘇 (平均葉長 > 60 cm) 則較低 (0~0.6%)。由新鮮山蘇葉片與其腐植質δ15N的分析發現 (新鮮山蘇葉 -6.5~-3.5‰,腐植質 -7~-3‰),然其中有4株山蘇之葉片異常呈現比腐植質為高的15N含量,其可能原因為,除山蘇在基質含有使「葉片15N變重」的動物性氮源外,同時亦受到可使「腐植質15N變輕」的外來枯落物之稀釋作用;而其中中型山蘇可能受動物性氮源之影響較大,而大型山蘇則由於較容易承接到大量外來枯落物。由∆δ15N可看出捕食者 (蜘蛛目及唇足綱,5.5~10‰) 較高於初級消費者 (植食者、碎食者以及食真菌者,1~7‰),∆δ13C測值則明顯可區分出植食者 (鱗翅目幼蟲,1~3.5‰)、食真菌者 (纓毛蕈蟲,3.52 ± 0.19‰) 及碎食者 (等腳目、寡毛綱及倍足綱,4.25~7.5‰),說明初級消費者間可能有不同之食源,尤其碎食者可能取食到C4、Crassulacean acid metabolism (CAM) 植物使其13C含量較高。由∆δ15N 分析家蟻亞科、山蟻亞科及蟋蟀科Duolandrevus sp. 等雜食者的食性層級,山蟻亞科應為初級消費者 (∆δ15N 3.73 ± 1.32‰),而家蟻亞科則介於捕食者與初級消費者間 (∆δ15N 5.76 ± 1.28‰),然家蟻亞科中捕食性的細毛瘤顎蟻∆δ15N較低 (4.94‰),蟋蟀科Duolandrevus sp.則屬於初級消費者 (∆δ15N 3.00 ± 1.03‰),顯示穩定同位素15N天然含量的分析可作為雜食性昆蟲食性分析之方法。 | zh_TW |
dc.description.abstract | Thirteen bird's nest ferns (Asplenium nidus L.) were collected from Fushan experimental forest. First, we separated the invertebrates from substrate, then measured the dry weight of the bird’s nest ferns and invertebrates to investigate the relationship between invertebrates and nest fern sizes. This investigation employed δ13C and δ15N analysis of sampled bird's nest ferns and invertebrate, to determine whether epiphytes derived nitrogen from animal sources with increased plant size. Trophic level was also analysied from stable isotope data of invertebrates. The nest fern total biomass and substrate biomass exponentially increased with mean leaf length and the biomass (or substrate) largely accumulated in 'large ferns' (mean leaf length > 60 cm). Invertebrates total biomass logarithmically increased with nest fern total biomass and linearly increased with nest fern total biomass using logarithmic transformation (R2 = 0.7, P < 0.01). It is concluded that the biomass accumulation of nest fern was different from invertebrates increasing with increased plant size. In 'medium ferns' (mean leaf length 40-60 cm) had higher invertebrate biomass (substrate-1) (0.3-2.2%), while both in 'small' (< 30 cm) and 'large' (> 60 cm) ferns had lower invertebrate biomass (substrate-1). Contrary to soil-plant systems, we found 4 nest ferns' δ15Nfern leaf higher than δ15Nhumus (fern leaf -6.5--3.5‰, humus -7--3‰), potentially besides the available N from animals sources (enriched-15N) absorbed by plants, the influence of a large amount of decomposed imported litter (depleted-15N) diluted the δ15N of humus also existed. Though the 'enriched' sources may be the main effect in 'medium ferns' and in the 'large ferns', the 'depleted' litter input may be the main factor because of the dilution of large amount imported litter received. ∆δ13C and ∆δ15N revealed trophic levels of invertebrates in 13 nest ferns. ∆δ15N of invertebrates distinguished into predators (Araneae and Chilopoda; 5.5-10‰) and primary consumers (herbivores, detritivores and fungivores; 1-7‰). ∆δ13C could further distinguish primary consumers into herbivores (Lepidoptera larvae; 1-3.5‰), fungivores (Ptiliidae; 3.52 ± 0.19‰) and detritivores (Isopoda, Oligochaeta and Diplopoda; 4.25-7.5‰) whereas the high value of detritivores’ ∆δ13C indicate they may have food sources from C4 and Crassulacean acid metabolism (CAM) plants in canopy. The trophic level analysis of omnivores (Myrmicinae, Formicinae and Gryllidae (Duolandrevus sp.)) by ∆δ15N revealed that Formicinae significantly aligned with primary consumers (unpaired t-test P > 0.01 with primary consumers; δ15N -2.355 ± 1.58‰,∆δ15N 3.725 ± 1.32‰), Myrmicinae aligned between predators and primary consumers (unpaired t-test P > 0.01 with 4 functional groups; δ15N -0.099 ± 1.36‰,∆δ15N 5.757 ± 1.28‰) and ∆δ15N of Strumigenys formosensis, one of the predators in Myrmicinae, was low (4.94‰), and Gryllidae (Duolandrevus sp.) also significantly aligned with primary consumers (unpaired t-test P > 0.01 with primary consumers; δ15N -2.414 ± 1.07‰,∆δ15N 3.000 ± 1.03‰). Our results confirm the use of 15N natural abundance in animal-diet studies of omnivorous species and exemplify the importance of trophic level study in epiphytes by stable isotope analysis. | en |
dc.description.provenance | Made available in DSpace on 2021-06-13T00:17:53Z (GMT). No. of bitstreams: 1 ntu-96-R93632003-1.pdf: 922755 bytes, checksum: bcea39853d404dba32d26f5335ae6356 (MD5) Previous issue date: 2007 | en |
dc.description.tableofcontents | 中文摘要 i
英文摘要 iii 目錄 v 表次 vii 圖次 viii 壹、緒言 1 貳、往昔研究 4 一、著生植物於森林環境中所扮演之角色 4 二、著生植物動物性氮來源之推測 4 三、穩定同位素15N 應用於著生植物氮源之研究 5 四、穩定同位素於食性層級之研究 8 參、材料與方法 12 一、試驗地點 12 二、植體以及土壤採集 12 三、無脊椎動物收集與分類 12 四、植物體與動物體生物量 13 五、元素分析及穩定同位素分析 15 六、資料分析 16 肆、結果 19 一、台灣山蘇花生物量與基質無脊椎動物生物量之關係 19 (一) 台灣山蘇花各部位生物量 19 (二) 台灣山蘇花各部位碳、氮含量 (%) 以及碳氮比 23 (三) 無脊椎動物相組成與功能群 26 (四) 台灣山蘇花生物量與無脊椎動物個體數及生物量之關係 33 二、台灣山蘇花與無脊椎動物之15N天然含量 37 (一) 台灣山蘇花15N天然含量 37 (二) 台灣山蘇花無脊椎動物15N天然含量組成 42 三、無脊椎動物食性層級之13C及15N天然含量 45 伍、討論 53 一、台灣山蘇花大小與基質無脊椎動物數量之關係 53 二、台灣山蘇花與無脊椎動物之15N天然含量 56 三、無脊椎動物食性層級之13C及15N天然含量 59 陸、結論 65 一、台灣山蘇花之動物性氮源 65 二、台灣山蘇花基質無脊動物相之食性層級 67 柒、引用文獻 69 捌、誌謝 79 玖、附錄 81 | |
dc.language.iso | zh-TW | |
dc.title | 台灣山蘇花基質氮源與無脊椎動物群聚之研究 | zh_TW |
dc.title | Study on the Nitrogen Source and Invertebrate Community in the Substrate of Bird's Nest Fern (Asplenium nidus L.) | en |
dc.type | Thesis | |
dc.date.schoolyear | 95-2 | |
dc.description.degree | 碩士 | |
dc.contributor.coadvisor | 王巧萍(Chiao-Ping Wang) | |
dc.contributor.oralexamcommittee | 陳秋男(Chiou-Nan Chen),謝蕙蓮(Hwey-Lian Hsieh),楊正澤(Jeng-Tze Yang) | |
dc.subject.keyword | 台灣山蘇花,Asplenium nidus,穩定同位素分析,天然含量,食性功能群, | zh_TW |
dc.subject.keyword | Asplenium nidus,stable isotope analysis,natural abundance,trophic functional groups, | en |
dc.relation.page | 97 | |
dc.rights.note | 有償授權 | |
dc.date.accepted | 2007-07-27 | |
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 | |
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ntu-96-1.pdf 目前未授權公開取用 | 901.13 kB | Adobe PDF |
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