請用此 Handle URI 來引用此文件:
http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/15875
完整後設資料紀錄
DC 欄位 | 值 | 語言 |
---|---|---|
dc.contributor.advisor | 張育森 | |
dc.contributor.author | Yu-Hsin Chen | en |
dc.contributor.author | 陳昱心 | zh_TW |
dc.date.accessioned | 2021-06-07T17:54:15Z | - |
dc.date.copyright | 2012-08-20 | |
dc.date.issued | 2012 | |
dc.date.submitted | 2012-08-16 | |
dc.identifier.citation | 黃瀞頤. 2011. 土壤介質添加保水劑對花壇植物生育及水分利用之影響. 國立臺灣大學園藝學研究所碩士論文. 臺北.
張耿衡. 2011. 栽培介質及營養管理對火鶴花生育之影響. 國立臺灣大學農業化學研究所博士論文. 臺北. Abad, M., P. Noguera, R. Puchades, A. Maquieira, and V. Noguera. 2002. Physico-chemical and chemical properties of some coconut dusts for use as a peat substitute for containerized ornamental plants. Biores. Technol. 82:241-245. Abad, M., F. Fornes, C. Carrión, V. Noguera, P. Noguera, Á. Maquieira, and R. Puchades. 2005. Physical properties of various coconut coir dusts compared to peat. HortScience 40:2138-2144. Allen, E.R. and R.D. Andrews. 1997. Space age soil mix uses centuries-old zeolites. Golf Course Mgt. 65:61-66. Andrews, R.D., J.K. Anthony, J.A. Murphy, and A.M. Petrovic. 1999. Zeoponic materials allow rapid greens grow-in. Golf Course Mgt. 67:68-72. Awang, Y., A.S. Shaharom, R.B. Mohamad, and A. Selamat. 2009. Chemical and physical characteristics of cocopeat-based media mixtures and their effects on the growth and development of Celosia cristata. Amer. J. Agr. Biol. Sci. 4:63-71. Bilderback, T.E., S.L. Warren, J.S. Owen, and J.P. Albano. 2005. Healthy substrates need physicals too. HortTechnology 15:747-751. Boivin, M.A., M.P. Lamy, A. Gosselin, and B. Dansereau. 2001. Effect of artificial substrate depth on freezing injury of six herbaceous perennials grown in a green roof system. HortTechnology 11:409-412. Boodley, J.W. 1981. The commercial greenhouse. Delmar, Albany, N.Y. Bousselot, J.M., J.E. Klett, and R.D. Koski. 2011. Moisture content of extensive green roof substrate and growth response of 15 temperate plant species during dry down. HortScience 46:518-522. Bugbee, G.J. and C.R. Frink. 1986. Aeration of potting media and plant growth. Soil Sci. 141:438-441. Bunt, A.C. 1961. Some physical properties of pot plant composts and their effect on plant growth. Plant Soil 3:228-242. Bunt, A.C. 1983. Physical properties of mixtures of peats and minerals of different particle size and bulk density for potting substrates. Acta Hort. 150:143-153. Cantor, S.L. 2008. Green roofs in sustainable landscape design. WW Norton, N.Y. Chang, Y.J., Y.T. Chang, and H.J. Chen. 2007. A method for controlling hydrogen sulfide in water by adding soild phase oxygen. Bioresourse Technol. 98:478-483. De Boodt, M. and O. Verdonck. 1972. The physical properties of the substrates in horticulture. Acta Hort. 26:37-44. Dehgan, B., T.H. Yeager, and F.C. Almira. 1994. Photinia and Podocarpus growth response to hydrophilic polymer-amended medium. HortScience 29:641-644. Dole, J.M. and H.F. Wilkins. 2005. Floriculture : principles and species. 2nd ed. Prentice Hall, Upper Saddle River, N.J. Dunnett, N. and N. Kingsbury. 2004. Planting Green Roofs and Living Walls. Timber Press, Portland, USA. Durhman, A.K., D.B. Rowe, and C.L. Rugh. 2006. Effect of watering regimen on chlorophyll fluorescence and growth of selected green roof plant taxa. HortScience 41:1623-1628. Durhman, A.K. and D.B. Rowe, and C.L. Rugh. 2007. Effect of substrate depth on initial growth, coverage, and survival of 25 succulent green roof plant taxa. HortScience 42:588-595. Emilsson, T. and K. Rolf. 2005. Comparison of establishment methods for extensive green roofs in southern Sweden. Urban For. and Urban Greening 3:103–111. Evans, M.R., R.H. Stamps. 1996. Growth of beeding plants in sphagnum peat and coir dust-based substrate. J. Environ. Hort. 14:187-190. Flannery, R.L. and W.J. Busscher. 1982. Use of synthetic polymer in potting soils to improve water holding capacity. Commun. Soil. Sci. Plant Anal. 13:103-111. Fonteno, W.C. and T.E. Bilderback. 1993. Impact of hydrogel on physical properties of coarse-sstructured horticultural substrates. J. Amer. Soc. Hort. 118:217-222. Friedrich, C.R. 2005. Principles for selecting the proper components for a green roof growing media. Proc. 3rd Intl. Green roof conf.: Greening rooftops for sustainable communities 3:262-274. Getter, K.L., and D.B. Rowe. 2006. The role of extensive green roofs in sustainable development. HortScience 41:1276–1285. Getter, K.L. and D.B. Rowe. 2007. Effect of substrate depth and planting season on Sedum plug survival on green roofs. J. Environ. Hort. 25:95-99. Getter, K.L. and D.B. Rowe. 2008. Media depth influences Sedum green roof establishment. Urban Ecosyst. 11:361-372. Getter, K.L. and D.B. Rowe. 2009. Substrate depth influences Sedum plant community on a green roof. HortScience 44:401-407. Gil, P.M., R. Ferreyra, C. Barrera, and C. Zúňiga. 2011. Improving soil oxygenation with hydrogen peroxide injection into heavy clay loam soil : effect on plant water status, CO2 assimilation and biomass of avocado trees. Acta Hort. 889: 557-564. Grillas, S., M. Lucas, E. Bardopolou, S. Sarafopoulos, and M. Voulgari. 2001. Perlite based soilless culture system : current commercial applications and prospects. Acta Hort. 548:105-113. Handreck, K.A. 1993. Properties of coir dust, and its use in the formulation of soilless potting media. Commun. Soil. Sci. Plant Anal. 24:349-33. Herppich, W.B. and K. Peckmann. 1997. Responses of gas exchange, photosynthesis, nocturnal acid accumulation and water relations of Aptenia cordifolia to short-term drought and rewatering. J. Plant Physiol. 150:467-474. Hsu, H.H. and C.T. Chen. 2002. Observed and projected climate change in Taiwan. Meteorol. Atmos. Phys. 79:87-104. Krause, G.H. and E. Weis. 1991. Chlorophyll fluorescence and photosynthesis : the basics. Annu. Rev. Plant Physiol. 42:313-349. Lin, Y.J. and H.T. Lin. 2011. Thermal performance of different planting substrates and irrigation frequencies in extensive tropical rooftop greeneries. Building Environ. 46:345-355. Martin, C.E., M. Higley, and W.Z. Wang. 1988. Ecophysiological significance of CO2-recycling via crassulacean acid metabolism in Talinum calycinum Engelm. (Portulacaceae) Plant Physiol. 86:562-568. Mc Willians, E.L. 1970. Comparative rates of dark CO2 uptake and acidification in the Bromeliaceae, Orchidaceae, and Euphorbiaceae. Botanical Gazette 131:285-290. Meerow, A.W. 1994. Growth of two subtropical ornamentals using coir (coconut mesocarp pith) as a peat substitute. HortScience 29:1484-1486. Ming, D.W. and E.R. Allen. 1999. Zeoponic substrates for space applications : advances in the use of natural zeolites for plant growth. Natural Microporous Mater. Environ. Technol. 362:157-176. Monje, O.A. and B. Bugbee. 1992. Inherent limitations of nondestructive chlorophyll meters: a comparison of two types of meters. HortScience 27:69-71. Monterusso, M.A., D.B. Rowe, and C.L. Rugh. 2005. Establishmrnt and persistence of Sedum spp. and native taxa for green roof applications. HortScience 40:391-396. Mori, I.C., S. Utsugi., S. Tanakamaru., A. Tani, T. Enomoto, and M. Katsuhara. 2009. Biomarkers of green roof vegetation : anthocyanin and chlorophyll as stress marker pigments for plant stresses of roof environments. J. Environ. Eng. Mgt. 19:21-27. Nagase, N. and N. Dunnett. 2010. Drought tolerance in different vegetation types for extensive green roofs : effects of watering and diversity. Landscape Urban Planning 97:318-327. Nelson, P.V. 2003. Greenhouse operation and management. Prentice Hall, Englewood Cliffs, N.J. Olszewski, M.W., M.H. Holmes, and C.A. Young. 2010. Assessment of physical properties and stonecrop growth in green roof substrates amended with compost and hydrogel. HortTechnology 20:438-444. Olympios, C.M. 1992. Soilless media under protected cultivation. Rockwool, peat, perlite and other substrates. Acta Hort. 323:215-229. Orzolek, M.D. 1993. Use of hydrophilic polymers in horticulture. HortTechnology 3:41-44. Pachauri, R.K. and A. Reisinger. 2007. Climate change 2007: synthesis report. assessment report of the intergovernmental panel on climate change. IPCC, Geneva, Switzerland. Palta, J. 1990. Leaf chlorophyll content, p. 207-213. In: N. Goel anf J. Norman (eds.). Instrumentation sensing in optical and thermal infrared regions. Harwood Academic Publ. GmbH, London, England. Panayiotis, N., T. Panayiota, and C. Ioannis. 2003. Soil amendments reduce roof garden weight and influence the growth rate of Lantana. HortScience 38:618-622. Richardson, A.D., S.P. Duigan, and G.P. Berlyn. 2002. An evaluation of noninvasive methods to estimate foliar chlorophyll content. New Phytologist 153:185-194. Riviere, L.M., J.C. Foucard, and F. Lemaire. 1990. Irrigation of container crops according to the substrate. Scientia Hort. 43:339-349. Rowe, D. B., M. A. Monterusso, and C. L. Rugh. 2006. Assessment of heat-expanded slate and fertility requirements in green roof substrates. HortTechnology 16:471-477. Sayed, O.H., M.J. Earnshaw, and M. Cooper. 1994. Growth, water relations, and CAM induction in Sedum album in response to water stress. Biologia Plantarum 36 (3): 383-388. Sayed, O.H. 2001. Crassulacean acid metabolism 1975-2000, a check list. Photosynthetica 39: 339-352. Schmidtke, T., D. White, and C. Woolard. 1999. Oxygen release kinetics from solid phase oxygen in Arctic Alaska. J. Hazardous Mate. 64:157-165. Schulze-Ardey, C. and M. Schröder. 2002. Guidelines for the planning, Construction and Maintenance of Green Roofing. Forschungsgesellschaft Landschaf sentwick lung Landschaftsbau, Bonn, German. Siegel-Issem, C.M., J.A. Burger, R.F. Powers, F. Ponder, and S.C. Patterson. 2005. Seedling root growth as a function of soil density and water content. Soil Sci. Soc. Amer. J. 69:215–226. Smeal, D., H. Zhang. Chlorophyll meter evaluation for nitrogen management in corn. Commun. Soil Sci. Plant Anal. 25:1495-1503. Spomer, A.L. 1975. Small soil containers as experimental tools : soil water relations. Commun. Soil Sci. Plant Anal. 6:21-26. Stoley, L.H., Zentmyer, G.A., Klotz, L.J., and C.K. Labanauskas. 1967. Oxygen diffusion, water, and Phytophthora cinnamomi in root decay and nutrition of avocados. Proc. Amer. Soc. Hort. Sci. 90:67-76. Tabatabaie, S.J. and J. Nazari. 2007. Influence of nutrient concentrations and NaCl salinty on the growth, photosynthesis, and essential oil content of peppermint and lemon verbena. Turk. J. Agric. 31:245-253. Thuring, C.E., R.D. Berghage, and D.J. Beattie. 2010. Green roof plant responses to different substrate types and depths under various drought conditions. HortTechnology 20:395-401. Ting, I.P. 1985. Crassulacean acid metabolism. Ann. Rev. Plant Physiol. 36:595-622. VanWoert, N.D., D.B. Rowe, J.A. Andresen, C.L. Rugh, and L. Xiao. 2005. Watering regime and green roof substrate design affect Sedum plant growth. HortScience 40:659-664. Veen, B.W. 1988. Influence of oxygen deficiency on growth and function of plant roots. Plant Soil 111:259-266. Verdonck, O., D. Vleeschauwer, and M. De Boodt. 1981. The influence of the substrates on the plant growth. Acta Hort. 126:251-258. Verdonck, O., R. Penninck, and M. De Boodt. 1983. The physical properties of different horticultural substrate . Acta Hort. 150:155-160. Walter, S., H. Heuberger, and W.H. Schnitzler. 2004. Sensibility of different vegetables to oxygen deficiency and aeration with H2O2 in the rhizosphere. Acta Hort. 659:499-508. Wang, Y.T. and C.A. Boogher. 1987. Effect of a medium-incorporated hydrogel on plant growth and water use of two foliage species. J. Environ. Hort. 5:125-127. Wang, Y.T. and L.L. Gregg. 1990. Hydrophilic polymers-their response to soil amendments and effect on properties of a soiless potting mix. J. Amer. Soc. Hort. Sci. 115:943-948. Watson, G.W. and P. Kelsey. 2006. The impact of soil compaction on soil aeration and fine root density of Quercus palustris. Urban For. Urban Greening 4:69-74. Willits, D. and M. Peet. 1999. Using chlorophyll fluorescence to model leaf photosynthesis in greenhouse pepper and tomato. Acta Hort. 507:311-317. Yu, P.S., T.C. Yang, and C.C. Kuo. 2006. Evaluating long-term trends in annual and seasonal precipitation in Taiwan. Water Resour. Mgt. 20:1007-1023. | |
dc.identifier.uri | http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/15875 | - |
dc.description.abstract | 薄層綠屋頂以維持植物生長並達到低維護管理為目標,除了應選用適用於屋頂環境生長的植物種類外,介質條件亦扮演重要的角色。故本研究首先探討於臺灣北部氣候環境下適用之薄層綠屋頂介質特性及其相配合之維管方式,接著再進一步探討使用臺灣本土性介質 (水陶石) 或椰纖取代傳統介質與介質添加物 (如保水劑、植生沸石) 對綠屋頂植物生育之影響,最後再探討砂質壤土添加釋氧物質之可行性。藉由觀察植物生育表現以瞭解適用於臺灣北部春季氣候環境下之薄層綠屋頂介質特性及在不同給水條件中應搭配何種介質,針對薄荷 (Mentha sppiperita)、紅毛莧 (Acalypha pendula)、繁星花 (Pentas lanceolata)、麒麟花 (Euphorbia milii)、圓葉景天 (Sedum makinoi) 及白佛甲 (Sedum lineare ‘Variegatum’) 以三種介質配比 (泥炭苔:蛭石:真珠石 = 2:2:1、2:2:2、2:2:4 (v/v/v),代號分別為PVP221、PVP222、PVP224) 及三種灌溉頻度:未灌溉 (NI)、低頻度灌溉 (LFI,10分鐘/1次/1週)及高頻度灌溉(HFI,10分鐘/2次/1週) 進行試驗,結果顯示:使用保水性較佳介質PVP221,以NI及LFI處理可使薄荷、紅毛莧及繁星花生長較佳;使用通氣性較佳介質PVP224,薄荷生長於有無灌溉處理間之生長表現皆較差,紅毛莧及繁星花則於灌溉處理表現較佳,高低頻度間無顯著差異。麒麟花、圓葉景天及白佛甲則於介質與灌溉處理間無顯著差異。
以本土性介質水陶石取代部分或全部進口介質對綠屋頂植物生育之影響,針對花蔓草 (Aptenia cordifolia)、蔓花生 (Arachis duranensis)、鋪地錦竹草Tradescantia minima) 以四種混合介質:1-PCh11 (1-P:水陶石 = 1:1)、1-PCh21 (1-P:水陶石 = 2:1)、PVCh411 (泥炭苔:蛭石:水陶石 = 4:1:1) 及PVP222進行試驗,結果顯示:花蔓草、蔓花生及鋪地錦竹草以水分及EC值較高之介質PVCh411處理植株乾重較重。接著探討施肥及添加保水劑於水陶石混合介質對綠屋頂植物生育之影響,針對小葉到手香 (Plectranthus socotranum) 以五種混合介質:PCh11 (泥炭苔:水陶石 = 1:1)、PCh31 (泥炭苔:水陶石 = 3:1)、Ch (水陶石)、Ch+Mix-AS (水陶石與保水劑粉劑混合)、Ch+Bottom-AS (水陶石底部添加保水劑濕劑) 配合兩種肥培處理:NF (未施肥) 及F (每週施用一次peter’s 20-20-20 ) 進行試驗,結果顯示:未施肥處理下,小葉到手香以EC值較高之介質Ch+Bottom-AS處理植株乾重較重;施肥處理下,以保水保肥性佳之PCh31介質處理植株乾重較重。水陶石介質雖具有良通氣性,但保水性及保肥性差,且pH值高,因此,可與保水性較高之泥炭苔或保水劑混合施用效果較佳。以環保觀點考量,探討椰纖取代泥炭苔,及添加植生沸石之可行性,針對越橘葉蔓榕 (Ficus vaccinioides) 以四種混合介質:PCh31、CCh31 (椰纖:水陶石 = 3:1)、CCh31+Z (95% CCh31椰纖混合介質+ 5 %植生沸石) 及PVP222 配合三種肥培管理 (分別添加0、1.5、3 g•L-1緩效性肥料) 進行試驗,結果顯示:不同肥培處理下,介質PCh31與CCh31之植株生育表現無顯著差異,此外CCh31+Z與CCh31比,對植株生育表現於各肥培處理間無顯著差異,但會降低植株生長表現指數。最後針對通氣性較差之介質,評估釋氧物質於栽培使用之可行性。針對花蔓草及越橘葉蔓榕以砂質壤土混合介質添加不同劑量 (0、0.1、0.5、1.0 g•L-1) 釋氧物質進行試驗,結果顯示添加0.1至1.0 g•L-1釋氧物質短期內並不會影響植物生長,但可提高介質pH值、EC值,及降低硬度。總而言之,理想的薄層綠屋頂栽培介質除需具備適當通氣性 (充氣孔隙度 > 10%),若兼具良好保水性 (容器容水量 > 35%),即可減少給水頻度,以維持植物生長並達到低維護管理之目的;若需植物生長良好,可選用EC值達最低限度 (EC值 > 0.05 dS•m-1) 之混合介質如PCh31或施用肥料,若需施肥建議每升介質施用1.5克緩效性肥料即可。 | zh_TW |
dc.description.abstract | The objective of extensive green roofs is to maintain plant growth with low-maintenance management. Besides using suitable plant species, it is crucial to select a suitable medium. Therefore, this study firstly investigated the effects of the medium and irrigation frequency on extensive green roofs under the north Taiwan’s climate, and further evaluated the effects of ceramic hydrous media, coir or medium amendments (such as hydrogels and zeoponics) on the growth of green roof plants. In addition, the feasibility of using oxygen-releasing compound (ORC) in a sandy loam-based medium was also explored. The effects of the medium and irrigation frequency on extensive green roofs under the north Taiwan’s climate were investigated. Mentha sppiperita, Acalypha pendula, Pentas lanceolata, Euphorbia milii, Sedum makinoi and Sedum lineare ‘Variegatum’ were grown in three growing mix [peat moss : vermiculite : perlite = 2:2:1, 2:2:2, 2:2:4 (v/v/v), named PVP221, PVP222, PVP224, respectively] under three irrigation frequencies [no irrigation (NI), low frequency irrigation (LFI, 10 minutes watering once a week), high frequency irrigation (HFI, 10 minutes watering twice a week )]. The results indicated that using a growing mix with high water-holding capacity (PVP221) enabled Mentha sppiperita, Acalypha pendula, and Pentas lanceolata to grow better under NI or LFI treatments. Using a growing mix with high aeration (PVP224) enabled Acalypha pendula and Pentas lanceolata to grow better under LFI or HFI treatments, but Mentha sppiperita to grow worse. No significant difference was observed for Euphorbia milii, Sedum makinoi, and Sedum lineare ‘Variegatum’ among all medium and irrigation treatments. The feasibility of using a local medium (ceramic hydrous media) to replace the imported media on the growth of green roof plants was evaluated. Aptenia cordifolia, Arachis duranensis, and Tradescantia minima were grown in four growing mix [1-PCh11 (1-P : ceramic hydrous media = 1:1), 1-PCh21 (1-P : ceramic hydrous media = 2:1), PVCh411 (peat moss : vermiculite : ceramic hydrous media = 4:1:1), and PVP222] under low-maintenance management. The results indicated that using a growing mix with higher water-holding capacity and electrical conductivity (PVCh411) enabled Aptenia cordifolia, Arachis duranensis, and Tradescantia minima to have more dry weight. The effects of ceramic hydrous and hydrogel amendment under various fertilization treatments on the growth of green roof plants was evaluated. Plectranthus socotranum was grown in five growing mix [PCh11 (peat moss : ceramic hydrous media = 1:1), PCh31 (peat moss : ceramic hydrous media = 3:1), Ch (ceramic hydrous media), Ch+Mix-AS (ceramic hydrous mixed with 3 g•L-1 Alcosorb®), and Ch+Bottom-AS (with 3 g•L-1 Alcosorb® placed under medium )] under two fertilization treatments [NF (no fertilization), F (200 ppm N from Peter’s 20-20-20, once a week)]. The results indicated that using a growing mix with higher electrical conductivity (Ch+Bottom-AS) enabled Plectranthus socotranum to have more dry weight under NF treatment. However, using a growing mix with higher water-holding capacity and cation exchange capacity (PCh31) enabled Plectranthus socotranum to have more dry weight under F treatment. Ceramic hydrous has higher aeration, but lower water-holding capacity and cation exchange capacity, and higher pH; therefore, it should be mixed with a higher water-holding capacity medium, such as peat moss or hydrogels. Considering the environmental sustainability, we explored the feasibility of peat moss being replaced by coir and adding zeoponics amendment. Ficus vaccinioides was grown in four growing mix [PCh31, CCh31 (coir : ceramic hydrous media = 3:1), CCh31+Z (95% CCh31 + 5% zeoponics), PVP222] under three fertilization treatments (slow-releasing fertilizer at rate of 0, 1.5, or 3 g•L-1). The results indicated that Ficus vaccinioides grown in PCh31 and CCh31 had no significant difference under various fertilization treatments. Ficus vaccinioides also had no significant difference between that was grown in CCh31+Z and CCh31. Finally, the feasibility of using ORC in a medium with inferior aeration was explored. Aptenia cordifolia and Ficus vaccinioides were grown with a sandy loam-based medium incorporated with 0, 0.1, 0.5, or 1.0 g•L-1 ORC. The overall plant growth did not exhibit a significant difference when 0.1-1.0 g•L-1 ORC was incorporated with the medium for two months. But the pH and electrical conductivity of the medium were higher, the hardness of the medium was lower. In conclusion, a suitable extensive green roof medium should have proper aeration (air-filled porosity > 10%) and excellent water-holding capacity (container capacity > 35%), it can reduce the irrigation frequency to maintain plant growth and achieve the low-maintenance management. To achieve optimal plant growth, the growing mix should have the minimal electrical conductivity (electrical conductivity > 0.05 dS•m-1), such as PCh31, or application of fertilizers is preferable. The application of 1.5 g of slow-releasing fertilizer per liter of medium is recommended. | en |
dc.description.provenance | Made available in DSpace on 2021-06-07T17:54:15Z (GMT). No. of bitstreams: 1 ntu-101-R99628115-1.pdf: 2544982 bytes, checksum: ea303acefd686f8835321d6c26446956 (MD5) Previous issue date: 2012 | en |
dc.description.tableofcontents | 摘要...................................................................I
Abstract.............................................................III 表目錄..............................................................VIII 圖目錄.................................................................X 第一章 前言............................................................1 第二章 前人研究........................................................3 一、常用無土介質之簡介.................................................3 (一) 有機無土介質......................................................3 (二) 無機無土介質......................................................4 二、介質添加物.........................................................5 (一) 保水劑 (Hydrogels)................................................5 (二) 植生沸石 (Zeoponics)..............................................5 (三) 釋氧物質 (Oxygen-releasing compound, ORC).........................6 三、栽培介質之理化特性.................................................6 (一) 物理特性..........................................................6 (二) 化學特性..........................................................7 四、綠屋頂常用介質種類及特性...........................................8 五、介質組成與厚度對綠屋頂植物生育之影響...............................9 六、灌溉對綠屋頂植物生育之影響........................................10 第三章 介質配比與灌溉頻度對綠屋頂植物生育之影響.......................11 摘要 (Abstract).......................................................11 一、前言 (Introduction)...............................................12 二、材料與方法 (Material and Methods).................................13 (一) 試驗設計.........................................................13 (二) 調查項目.........................................................13 (三) 統計分析.........................................................16 三、結果 (Results)....................................................17 四、討論 (Discussion).................................................20 五、結論 (Conclusion).................................................23 第四章 水陶石混合介質對綠屋頂植物生育之影響...........................32 摘要 (Abstract).......................................................32 一、前言 (Introduction)...............................................33 二、材料與方法 (Material and Methods).................................33 (一) 試驗一 水陶石混合介質對花蔓草、蔓花生及鋪地錦竹草生育之影響......33 (二) 試驗二 肥培處理於水陶石混合介質對小葉到手香生育之影響............34 (三) 調查項目.........................................................35 (四) 統計分析.........................................................36 三、結果 (Results)....................................................37 四、討論 (Discussion).................................................40 五、結論 (Conclusion).................................................43 第五章 椰纖混合介質對越橘葉蔓榕生育之影響.............................60 摘要 (Abstract).......................................................60 一、前言 (Introduction)...............................................61 二、材料與方法 (Material and Methods).................................61 (一) 試驗設計.........................................................61 (二) 調查項目.........................................................62 (三) 統計分析.........................................................62 三、結果 (Results)....................................................63 四、討論 (Discussion).................................................64 五、結論 (Conclusion).................................................66 第六章 砂質壤土混合介質添加釋氧物質對綠屋頂植物生育之影響.............74 摘要 (Abstract).......................................................74 一、前言 (Introduction)...............................................75 二、材料與方法 (Material and Methods).................................75 (一) 試驗設計.........................................................75 (二) 調查項目.........................................................76 (三) 統計分析.........................................................77 三、結果 (Results)....................................................77 四、討論 (Discussion).................................................78 五、結論 (Conclusion).................................................79 第七章 結論與建議.....................................................89 參考文獻 (References).................................................90 附錄 (Appendix).......................................................96 | |
dc.language.iso | zh-TW | |
dc.title | 介質特性與栽培管理對綠屋頂植物生育之影響 | zh_TW |
dc.title | Effects of Medium Properties and Cultivation on Growth of Green Roof Plants | en |
dc.type | Thesis | |
dc.date.schoolyear | 100-2 | |
dc.description.degree | 碩士 | |
dc.contributor.oralexamcommittee | 鍾仁賜,黃裕銘,黃光亮 | |
dc.subject.keyword | 水陶石,薄層綠屋頂,保水劑,灌溉,介質添加物,釋氧物質,植生沸石, | zh_TW |
dc.subject.keyword | Ceramic hydrous media,Extensive green roof,Hydrogels,Irrigation,Medium amendments,Oxygen-releasing compound,Zeoponics, | en |
dc.relation.page | 100 | |
dc.rights.note | 未授權 | |
dc.date.accepted | 2012-08-17 | |
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-101-1.pdf 目前未授權公開取用 | 2.49 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。