遮光、溫度與無機養分對擎天鳳梨‘Cherry’生長之影響

Chao-Yi Lin; 林昭儀

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/33610

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	葉德銘(Der-Ming Yeh)
dc.contributor.author	Chao-Yi Lin	en
dc.contributor.author	林昭儀	zh_TW
dc.date.accessioned	2021-06-13T04:50:19Z	-
dc.date.available	2006-07-21
dc.date.copyright	2006-07-21
dc.date.issued	2006
dc.date.submitted	2006-07-15
dc.identifier.citation	成美園藝 2004. 大陸盆花訊息台灣花卉園藝 204:20-23 李佳紋 2005. 遮光、氮素濃度與溫度對美人蕉及美鐵芋生長之影響國立台灣大學園藝研究所碩士論文 132 pp. 林立 1998. 無機養分、溫度與光度對白鶴芋生長之影響國立台灣大學園藝研究所碩士論文 101 pp. 阮育雄 2003. 鳳梨花外銷中國大陸之潛力與策略台灣花卉園藝 193:16-20 施昭彰 1979. 不同氮鉀肥濃度、溫度及GA3對菊花生長與開花之影響國立台灣大學園藝研究所碩士論文 116 pp. 許哲夫 2004. 觀賞鳳梨產業發展及品種介紹高雄區農業專訊 50:9-12 郭倩妤 2005. 硼、氯化鈉、儲運、溫度與澆水頻率對擎天鳳梨葉片生長與產後品質之影響國立台灣大學園藝研究所碩士論文 150 pp. 黃肇家黃慧穗蔡金玉 2003. 觀賞鳳梨盆花海運溫度及對品質之影響台灣花卉園藝 194:52-56 葉德銘林立 1999. 氮素濃度與型態對綠巨人白鶴芋生長之影響中國園藝 45:160-167 葉德銘李哖 1988. 溫度對臺灣山蘇花生長之影響中國園藝 34:303-310 楊光盛 1991. 肥料推薦量系統模式建立研究國立台灣大學農化所博士論文 168 pp. Baghour, M., E. Sanchez, J. M. Ruiz, and L. Romero. 2001. Metabolism and efficiency of phosphorus utilization during senescence in pepper plants: Response to nitrogenous and potassium fertilization. J. Plant Nutr. 24:1731-1743. Benzing, D. H. 1973. The monocotyledons: their evolution and comparative biology. I. Mineral nutrition and related phenomena in Bromeliaceae and Orchidaceae. Quar. Rev. Boil. 48:277-290. Benzing, D. H. 2000. Bromeliaceae: Profile of an adaptive radiation. Cambridge University Press, UK, 675 pp. Benzing, D. H. and A. Renfrow. 1974. The mineral nutrition of Bromeliaceae. Bot. Gaz. 135:281-288. Benzing, D. H., K. Henderson, B. Kessel, and J. Sulak. 1976. The absorptive capacities of bromeliad trichomes. Amer. J. Bot. 63:1009-1014. Bermudes, D. and D. H. Benzing. 1991. Nitrogen fixation in association with Ecuadorean bromeliads. J. Trop. Ecol. 7:531-536. Bhatti, A. S., S. Steinert, G. Sarwar, A. Hilpert and W. D. Jeschke. 1993. Ion distribution in relation to leaf age in Leptochloa fusca (L.) Kunth (Kallar grass). New phytol. 123:539-545. Broschat, T. K. 2002. Influence of light intensity on optimum fertilization rate in five species of tropical ornamental plants. HortTechnology 12:226-229. Castro-Hernandez, J. C., J. H. D. Wolf, J. G. Garcia-Franco, and M. Gonzalez-Espinosa. 1999. The influence of humidity, nutrients and light on the establishment of the epiphytic bromeliad Tillandsia guatemalensis in the highlands of Chiapas, Mexico. Revista de Biologia Tropical 47:763-773. Chase, A. R. 1987. Compendium of ornamental foliage plant diseases. The American Phytopathological Society. USA, pp.71-86. Chase, A. R. 1997. Foliage plant diseases: Diagnosis and control. The American Phytopathological Society. USA, pp.22-23. Collard, R. C., J. N. Joiner, C. A. Conover, and D. B. McConnell. 1977. Influence of shade and fertilizer on light compensation point of Ficus benjamina L. J. Amer. Soc. Hort. Sci. 102:447-449. Conley, M. E., E. T. Paparozzi, and W. W. Stroup. 2002. Leaf anatomical and nutrient concentration responses to nitrogen and sulfur applications in poinsettia. J. Plant Nutr. 25:1773-1791. Conover, C. A. and R. T. Poole. 1975. Influence of shade and fertilizer levels on production and acclimatization of Dracaena marginata. Proc. Fla. State Hort. Soc. 88:606-608. Conover, C. A. and R. T. Poole. 1981. Influence of light and fertilizer levels and fertilizer sources on foliage plants maintained under interior environments for one year. J. Amer. Soc. Hort. Sci. 106:571-574. Endres, L. and H. Mercier. 2001a. Ammonium and urea as nitrogen sources for bromeliads. J. Plant Physiol. 158: 205-212. Endres, L. and H. Mercier. 2001b. Influence of nitrogen forms on the growth and nitrogen metabolism of bromeliads. J. Plant Nutri. 24: 29-42. Epstein, E. and A. J. Bloom. 2005. Mineral nutrition of plants: Principles and perspectives. Sinauer Associates. USA. 400 pp. Fails, B. S., A. J. Lewis and J. A. Barden. 1982. Anatomy and morphology of sun- and shade- grown Ficus benjamina. J. Amer. Soc. Hort. Sci. 107: 754-757. Fernandes, J., R. M. Chaloub, and F. Reinert. 2002. Influence of nitrogensupply on the photoprotective response of Neoregelia cruenta under high and low light intensity. Funct. Plant Biol. 29:757-762. Fisher, B. D., E. R. Emino and G. J. Gogue. 1986. Morphological differences in Neoregelia trichomes and uptake of foliar-applied copper. J. Amer. Soc. Hort. Sci. 111:90-94. Fricke, W., P. S. Hinde, R. A. Leigh, and A. D. Tomos. 1995. Vacuolar solutes in the upper epidermis of barley leaves. Planta 196:40-49. Griffith, L. P. 1998. Tropical foliage plants: A grower’s guide. Ball publisging. USA, p.40-47. Haley, T. B. and D. W. Reed. 2004. Optimum potassium concentrations in recirculating subirrigation for selected greenhouse crops. HortScience 39:1441-1444. Haslam, R., A. Borland, K. Maxwell and H. Griffiths. 2003. Physiological response of the CAM epiphyte Tillandsia usneoides L. (Bromeliaceae) to variations in light and water supply. J. Plant Physiol. 160:627-634. Hay, J. D., L. D. de Lacerda, and A. L. Tan. 1981. Soil cation increase in a tropical sand dune ecosystem due to a terrestrial bromeliad. Ecology 62:1392-1395. Jimenez, S. and M. T. Lao. 2005. Influence of nitrogen form on the quality of Dieffenbachia amoena ‘Tropic Snow’. HortScience 40:386-390. Johnson, C. R., T. A. Nell, J. N. Joiner and J. K. Krantz. 1979. Effects of light intensity and potassium on leaf stomatal activity of Ficus benjamina L. HortScience 14:277-278. Kang, J. G. and M. W. van Iersel. 2001. Interactions between temperature and fertilizer concentration affect growth of subirrigated petunias. J. Plant Nutri. 24:753-765. Kuo, C. Y. and D. M. Yeh. 2006. Effects of boric acid concentration and shading on growth, leaf phy siology, and anatomy of Guzmania. HortScience 41:618-621. Londer, E., J. Ceusters, I. Vervaeke, R. Deroose, and M. P. De Proft. 2005. Organic acid analysis and plant water status of two Aechmea cultivars grown under greenhouse conditions: Implications on leaf quality. Scientia Hort. 105:249-262. Loneragan, J. F. and C. J. Asher. 1967. Response of plants to phosphate concentration in solution culture. II. Rate of phosphate absorption and its relation to growth. Soil Sci. 103:311–318. Luciana, C. C., D. R. de Almeida and C. F. D. Rocha. 1998. Phenotypic response of Neoregelia johannis (Bromeliaceae) dependent on light intensity reaching the plant microhabitat. Selbyana 19:240-244. Mak, A. T. Y. and D. M. Yeh. 2001. Nitrogen nutrition of Spathiphyllum ‘Sensation' grown in sphagnum peat-based and coir-based media and two irrigation methods. HortScience 36:645-649. Mankin, K. R. and R. P. Fynn. 1996. Nutrient uptake response of New Guinea impatiens to light, Temperature, and nutrient solution concentration. J. Amer. Soc. Hort. Sci. 121:826-830. Marlatt, R. B. 1974. Chilling injury in Sansevieria. HortScience 9:539-540. Martin, C. E. 1994. Physiological ecology of the Bromeliaceae. Bot. Rev. 60:1-82. Martin, C. E., A. Tuffers, W. B. Herppich and D. J. von Willert. 1999. Utilization and dissipation of absorbed light energy in the epiphytic crassulacean acid metabolism bromeliad Tillandsia ionatha. Int. J. Plant Sci. 160:307-313. Martin, C. E., K. W. McLeod, C. A. Eades and A. F. Pitzer. 1985. Morphological and physiological responses to irradiance in the CAM epiphyte Tillandsia usneoides L. (Bromeliaceae). Bot. Gaz. 146:489-494. Maxwell, K. 2002. Resistance is useful: diurnal patterns of photosynthesis in C3 and crassulacean acid metabolism epiphytic bromeliads. Funct. Plant Boil. 29:679-687. Maxwell, K., J. L. Marrison, R. M. Leech, H. Griffiths and P. Horton. 1999. Chloroplast acclimation in leaves of Guzmania monostachia in response to high light. Plant Physiol. 121:89-95. Mercier, H., G. B. Kerbauy, B. Sotta, and E. Miginiac. 1997. Effects of NO3-, NH4+ and urea nutrition on endogenous levels of IAA and four cytokinins in two epiphytic bromeliads. Plant Cell Environ. 20: 387-392. Mercier, H. and G. B. Kerbauy. 1997. Growth and GDH and AAT isoenzyme patterns in terrestrial and epiphytic bromeliads as influenced by nitrogen source. Selbyana 18:89-94. Nadkarni, N. M. and R. B. Primack. 1989. The use of gamma spectrometry to measure within-plant nutrient allocation of a tank bromeliad, Guzmania lingulata. Selbyana 11:22-25. Nemali, K. S. and M. W. van Iersel. 2004a. Light intensity and fertilizer concentration: I. Estimating optimal fertilizer concentrations from water-use efficiency of wax begonia. HortScience 39:1287-1292. Nemali, K. S. and M. W. van Iersel. 2004b. Light intensity and fertilizer concentration: II. Optimal fertilizer solution concentration for species deffering in light requirement and growth rate. HortScience 39:1293-1297. Nievola, C.C., H. Mercier, and N. Majerowicz. 2001. Levels of nitrogen assimilation in bromeliads with different growth habits. J. Plant Nutri. 24: 1387-1398. Nowak, E. J. and C. E. Martin. 1997. Physiological and anatomical responses to water deficits in the CAM epiphyte Tillandsia ionantha (Bromeliaceae). Int. J. Plant Sci. 158:818-826. Oguchi, R., K. Hikosaka and T. Hirose. 2003. Does the photosynthetic light-acclimation need change in leaf anatomy? Plant Cell Environ. 26:505-512. Parkhurst, R. W. 2000. The book of bromeliads and Hawaiian tropical flowers. Pacific Isle Publish. Comp. USA, 216 pp. Pearcy, R. W., F. Valladares, S. J. Wright and E. L. de Paulis. 2004. A functional analysis of the crown architecture of tropical forest Psychotria species: Do species vary in light capture efficiency and consequently in carbon gain and growth? Oecologia 139:163-177. Pia, W. L., N. Günter, B. Fritz, and E. Christof. 2000. Rapid effects of nitrogen form on leaf morphogenesis in tobacco. J. Exp. Bot. 51:227-237. Pierce, S., K. Maxwell, H. Griffiths and K. Winter. 2001. Hydrophobic trichome layers and epicuticular wax powders in Bromeliaceae. Amer. J. Bot. 88:1371-1389. Popp, M., H. P. Janett, U. Luttge, and E. Medina. 2003. Metabolite gradients and carbohydrate translocation in rosette leaves of CAM and C3 bromeliads. New Phytol. 157:649-656. Richardson, B. A., M. J. Richardson, F. N. Scatena, and W. H. McDowell. 2000. Effects of nutrient availability and other elevational changes on bromeliad populations and their invertebrate communities in a humid tropical forest in Puerto Rico. J. Trop. Ecol. 16:167-188. Reich, A., J. J. Ewel, and N. M. Nadkarni. 2003. Nitrogen isotope ratios shift with plant size in tropical bromeliads. Oecologia 137:587-590. Rose, M. A. and J. W. White. 1994. Nitrogen rate and timing of nitrogen application in poinsettia (Euphorbia pulcherrima Willd. Ex Klotz.) HortScience 29:1309-1313. Sabreen, S. and S. Saiga. 2004. Potassium level suitable for screening high magnesium containing grass seedlings under solution culture. J. Plant Nutr. 27:1015-1027. Scoggins, H. L. and H. A. Mills. 1998. Poinsettia growth, tissue nutrient concentration, and nutrient uptake as influenced by nitrogen form and stage of growth. J. Plant Nutr. 21:191-198. Shen, G. W. H. and J. G. Seeley. 1983. The effect of shading and nutrient supply on variegation and nutrient content of variegated cultivars of Peperomia obtusifolia. J. Amer. Soc. Hort. Sci. 108:429-433. Steens, A. 2003. Bromeliads for the contemporary garden. Timber Press. U.K. 196 pp. Tan, L. P., J. He and S. K. Lee. 2002. Effects of root-zone temperature on the root development and nutrient uptake of Lactuca sativa L. ‘Panama’ grown in an aeroponic system in the tropics. J. Plant Nutri. 25:297-314. Watanabe, F. S., W. L. Lindsay, and S. R. Olsen. 1965. Nutrient balance involving phosphorus, iron and zinc. Soil Sci. Soc. Amer. Proc. 29:562–565. Whitcher, C. L., M. W. Kent and D. W. Reed. 2005. Phosphorus concentration affects New Guinea impatiens and vinca in recirulating subirrigation. HortScience 40:2047-2051. Williams, B.E. and I. Hodgson. 1990. Growing bromeliads. Christopher Helm. London. 150 pp. Wright, R. D. 1986. The pour-through nutrient extraction procedure. HortScience 21:227-229. Xu, G., S. Wolf and U. Kafkafi. 2002. Ammonium on potassium interaction in sweet pepper. J. Plant Nutr. 25:719-734. Yamada, T., T. Okuda, M. Abdullah, M. Awang and A. Furukawa. 2000. The leaf development process and its significance for reducing self-shading of a tropical pioneer tree species. Oecologia 125:476-482. Yeh, D. M., L. Lin and C. J. Wright. 2000. Effects of mineral nutrient deficiencies on leaf development, visual symptoms and shoot-root ratio of Spathiphyllum. Scientia Hort. 86:223-233. Zhang, D., R. E. Moran and L. B. Stack. 2004. Effect of phosphorus fertilization on growth and flowering of Scaevola aemula R. Br. ‘New Wonder’. HortScience 39:1728-1731. Zotz, G., A. Enslin, W. Hartung, and H. Ziegler. 2004. Physiological and anatomical changes during the early ontogeny of the heteroblastic bromeliad, Vriesea sanginolenta, do not concur with the morphological change form atmospheric to tank form. Plant Cell Environ. 27:1341-1350. Zotz, G. and P. Hietz. 2001. The physiological ecology of vascular epiphytes: Current knowledge, open questions. J. Exp. Bot. 52:2067-2078. Zotz, G., P. Reichling and F. Valladares. 2002. A simulation study on the importance of size-related changes in leaf morphology and physiology for carbon gain in an epiphytic bromeliad. Ann. Bot. 90: 437-443. Zotz, G. and V. Thomas. 1999. How much water is in the tank? Model calculations for two epiphytic bromeliads. Ann. Bot. 83:183-192.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/33610	-
dc.description.abstract	擎天鳳梨之花苞片顏色鮮豔且觀賞期可長達半年，為優良之景觀擺設或室內觀賞盆栽，然而目前仍缺乏光度、溫度及養分供應相關科學性研究，因此本試驗主要目的為了解光度、溫度及肥培管理等栽培條件對擎天鳳梨‘Cherry’營養生長之影響。巨量元素於擎天鳳梨葉片中分布有差異，K及Ca濃度呈現梯度分佈，葉基K濃度顯著向葉尖逐漸減少，Ca濃度則由葉基向葉尖逐漸增加。當遮陰程度增加至77 %(中午平均光度214 μmol•m-2•s-1)，植株總葉面積、新生長葉片數量、地上部乾重及根部生長明顯降低。葉片綠色組織厚度隨光度提高而增厚，放射狀細胞內的葉綠體顯著較多。在20 %遮陰下生長之葉片K濃度顯著較高。以25/20℃配合施用100 %強生氏營養液較有利於擎天鳳梨營養生長，具較高地上部、根部乾重、總葉面積及新生長葉片數。當養液濃度由50 %提高至200 %強生氏營養液，葉片長度增加。與25/20℃和20/15℃處理相比，以30/25℃處理之葉片顯著較薄且較長。較高溫度(35/30℃、30/25℃)下加速葉片水分散失，葉尖焦枯及內捲葉片數目顯著增加。施用P濃度15-131 mg•L-1範圍內，擎天鳳梨葉片P濃度由1.2 g•kg-1提高至5.4 g•kg-1，兩者呈高度直線正相關。以10N-13.1P-16.6K處理之葉片P濃度明顯已超過適當濃度，植株葉片數、株高、根部乾重、葉綠素計讀值、葉片寬度等生長受到抑制，大量葉片黃化或焦枯。施用15 mM完全銨態氮處理者之新生長葉片數、株高、葉面積、地上部乾重及根部乾重皆明顯較低，植株葉尖或葉緣出現大量淡黃及褐色壞疽。硝酸態氮及尿素處理之植株外觀形態不同，尿素處理之株高及幅寬皆比硝酸態氮處理小，葉片形狀短胖，長寬比明顯較小，且尿素態氮較有利於葉片及葉面積的增加。擎天鳳梨對氮需求低且利用效率高，氮濃度由0 mM增加為施用4 mM時，葉片綠色組織厚度、葉綠素計讀值與生長量顯著增加，其植株淨光合作用能力亦較其他處理者高。然而施用16 mM N較有利於營養生長，其總葉面積、地上部乾重及根部乾重較高。施用N濃度0-32 mM範圍內，葉片N濃度由6.0 g•kg-1提高至27.5 g•kg-1，兩者呈直線正相關。地上部乾重與根部乾重為直線正相關。施用0 mM K時，葉片寬度顯著減小。隨施用K濃度提高至6 mM，老葉(第15片葉)之K濃度顯著增加，葉片總厚度、上表皮及儲水組織厚度顯著增加，植株老葉出現黃斑及黃化葉片數亦減少。較高氮鉀比例(N16K2)處理下，葉片寬度顯著減少，黃斑及黃化葉片數則顯著增加。	zh_TW
dc.description.abstract	Plants of Guzmania lingulata have colorful bracts, making them widely used for landscape decoration or indoor potted flowers. Information on shading, temperature and nutrient supply is presently limited. The objectives of this thesis were to determine the effects of light intensity, temperature and nutrition on growth of G. lingulata ‘Cherry’. The distribution of K and Ca concentration was gradient in the G. lingulata ‘Cherry’ leaf blade. Leaf K concentration decreased, while Ca concentration increased, from leaf base to tip. Under 77 % shading (average noon PPF 214 μmol•m-2•s-1), the total leaf area, leaf number, shoot and root dry weights decreased. Mesophyll layer thickness increased with increasing irradiance. More and smaller chloroplasts were also observed in the mesophyll stellate cells under higher irradiances. Leaves grown under 20 % shade had a higher leaf K concentration. At 25/20℃, applying 100 % Johnson’s solution resulted in the highest shoot dry weight, root dry weight, total leaf area and new grown leaves of G. lingulata ‘Cherry’. Leaf length increased with increasing Johnson’s solution concentration from 50 % to 200 %. Leaves were thinner and slighter at 30/25℃ than those at 25/20℃ or 20/15℃. Number of the incurved and necrotic leaves increased as temperature increased. Applying P concentration from 15 to 131 mg•L-1 increased leaf P concentration linearly. Application of 10N-13.1P-16.6K decreased the leaf number, plant height, root dry weight, SPAD-502 value and blade width, and exceeded in leaf P concentration.	en
dc.description.provenance	Made available in DSpace on 2021-06-13T04:50:19Z (GMT). No. of bitstreams: 1 ntu-95-R93628114-1.pdf: 3917141 bytes, checksum: 3912ab66407c81931db58a6ab673966a (MD5) Previous issue date: 2006	en
dc.description.tableofcontents	第一章前言 (Introduction) 1 第二章前人研究 (Literature Review) 一、觀賞鳳梨之習性與分類 (Habitats and Taxonomy) 3 二、影響觀賞鳳梨生長之環境因子 (Environmental Factors Affecting Growth) 3 三、觀賞鳳梨之無機養分需求 (Mineral Nutrient Requirement) 6 四、影響觀賞鳳梨品質之因子 (Factors Affecting Plant Quality) 8 第三章一般材料與方法 (General Materials and Methods) 一、植物材料 10 二、試驗場地及栽培管理 10 三、調查項目與方法 10 四、統計分析 13 第四章擎天鳳梨葉片解剖及葉片巨量元素分布 (Anatomy and Macroelement Distribution of Guzmania ‘Cherry’ Leaves) 一、前言 14 二、材料與方法 15 三、結果與討論 15 第五章遮光及養液濃度對擎天鳳梨生長之影響 (Effects of Shading and Nutrient Solution Concentration on Growth of Guzmania ‘Cherry’) 一、前言 23 二、材料與方法 23 三、結果 24 四、討論 26 第六章溫度及養液濃度對擎天鳳梨生長之影響 (Effects of Temperature and Nutrient Solution Concentration on Growth of Guzmania ‘Cherry’) 一、前言 43 二、材料與方法 43 三、結果 44 四、討論 46 第七章肥料來源及氮型態對擎天鳳梨生長之影響 (Effects of Fertilizer Source and Nitrogen Form on Growth of Guzmania ‘Cherry’) 一、前言 56 二、材料與方法 57 三、結果 58 四、討論 61 第八章氮、鉀濃度及氮鉀比例對擎天鳳梨生長之影響 (Effects of Nitrogen and Potassium Concentration, and N/K Ratio on Growth of Guzmania ‘Cherry’) 一、前言 79 二、材料與方法 80 三、結果 81 四、討論 86 結論(Conclusion) 117 摘要(Summary) 117 參考文獻(References) 123 附錄(Appendix) 130
dc.language.iso	zh-TW
dc.title	遮光、溫度與無機養分對擎天鳳梨‘Cherry’生長之影響	zh_TW
dc.title	Effects of Shading, Temperature and Mineral Nutrient on the Growth of Guzmania ‘Cherry’	en
dc.type	Thesis
dc.date.schoolyear	94-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	李哖(Nean Lee),鍾仁賜(Ren-Shih Chung),張耀乾(Yao-Chien Chang)
dc.subject.keyword	擎天鳳梨,無機養分,鉀,氮型態,	zh_TW
dc.subject.keyword	Guzmania,mineral nutrient,potassium,N form,	en
dc.relation.page	131
dc.rights.note	有償授權
dc.date.accepted	2006-07-17
dc.contributor.author-college	生物資源暨農學院	zh_TW
dc.contributor.author-dept	園藝學研究所	zh_TW
顯示於系所單位：	園藝暨景觀學系

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	3.83 MB	Adobe PDF

顯示文件簡單紀錄

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。