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完整後設資料紀錄
DC 欄位 | 值 | 語言 |
---|---|---|
dc.contributor.advisor | 黃文達(Wen-Dar Huang) | |
dc.contributor.author | Ting-Yu Chou | en |
dc.contributor.author | 周庭聿 | zh_TW |
dc.date.accessioned | 2021-06-15T16:38:37Z | - |
dc.date.available | 2020-08-16 | |
dc.date.copyright | 2015-08-16 | |
dc.date.issued | 2015 | |
dc.date.submitted | 2015-08-12 | |
dc.identifier.citation | 王志清。2012。麻瘋樹葉片提取液對植物種子發芽的化感效應。現代農業科技。
10: 199-212。 付亮亮、鄭水、李嬌、黃權、金洪昆、王興紅。2011。利用小桐子餅生產有機肥 是小桐子餅利用的重要途徑。氨基酸和生物資源。33: 24-26。 吳志文、林素汝。2008。新興生質柴油作物-麻瘋樹。高雄區農業專訊。65: 10-11。 林娟、周選圍、唐克軒、陳放。2004。麻瘋樹植物資源研究概況。熱帶亞熱帶植 物學報。12: 285-290。 施欣慧、游漢明、傅春旭。2010。台灣痲瘋樹病蟲害報導。林業研究專訊。 17: 68-71。 許明晃、陳傑君、楊志維、黃文達、楊棋明。2013。痲瘋樹相剋作用之研究。中華民國雜草學會會刊。34: 195。 蔡芷妤。2012。激勃素調控痲瘋樹株高之研究與建立轉基因系統培育高產及半矮 化痲瘋樹品系。碩士論文。台北:台灣大學植物科學研究所。 劉朔、何朝均、何紹彬、朱子政、辜云杰、許曉明、唐小智、游秋明。2008。 不同施肥處理對麻瘋樹幼林生長的影響。四川林業科技。30: 53-56 劉方炎、李昆、孫永玉。2012。中國麻瘋樹研究進展與開發利用現狀。中國農業 大學學報。17: 178-184。 Abugre S, Quashie-Sam S (2010) Evaluating the allelopathic effect of Jatropha curcas aqueous extract on germination, radicle and plumule length of crops. International Journal of Agriculture and Biology 12: 769-772. Achten WM, Maes W, Reubens B, Mathijs E, Singh VP, Verchot L, Muys B (2010) Biomass production and allocation in Jatropha curcas L. seedlings under different levels of drought stress. Biomass and Bioenergy 34: 667-676. Achten WMJ, Verchot L, Franken YJ, Mathijs E, Singh VP, Aerts R, Muys B (2008) Jatropha bio-diesel production and use. Biomass and Bioenergy 32: 1063-1084. Alkorta I, Hernández-Allica J, Becerril J, Amezaga I, Albizu I, Garbisu C (2004) Recent findings on the phytoremediation of soils contaminated with environmentally toxic heavy metals and metalloids such as zinc, cadmium, lead, and arsenic. Reviews in Environmental Science and Biotechnology 3: 71-90. Augustus G, Jayabalan M, Seiler G (2002) Evaluation and bioinduction of energy components of Jatropha curcas. Biomass and Bioenergy 23: 161-164. Bártoli J (2008) Physic Nut (Jatropha curcas) Cultivation in Honduras Handbook. Agricultural Communication Center of the Honduran Foundation for Agricultural Research. Behera SK, Srivastava P, Tripathi R, Singh J, Singh N (2010) Evaluation of plant performance of Jatropha curcas L. under different agro-practices for optimizing biomass–a case study. Biomass and Bioenergy 34: 30-41. Benito M, Masaguer A, Moliner A, Arrigo N, Palma RM (2003) Chemical and microbiological parameters for the characterisation of the stability and maturity of pruning waste compost. Biology and Fertility of Soils 37: 184-189. Bolhar-Nordenkampf H, Long S, Baker N, Oquist G, Schreiber U, Lechner E (1989) Chlorophyll fluorescence as a probe of the photosynthetic competence of leaves in the field: a review of current instrumentation. Functional Ecology: 497-514. Bonanomi G, Sicurezza MG, Caporaso S, Esposito A, Mazzoleni S (2006) Phytotoxicity dynamics of decaying plant materials. New Phytol 169: 571-578. Brittaine R, Lutaladio N (2010) Jatropha: a smallholder bioenergy crop: the potential for pro-poor development, Vol 8. Food and Agriculture Organization of the United Nations (FAO). Canarutto S, Petruzzelli G, Lubrano L, Guidi GV (1991) How composting affects heavy metal content. BioCycle 32. Chaturvedi S, Kumar A, Singh B, Nain L, Joshi M, Satya S (2013) Bioaugmented composting of Jatropha de-oiled cake and vegetable waste under aerobic and partial anaerobic conditions. J Basic Microbiol 53: 327-335 Chaves M, Flexas J, Pinheiro C (2009) Photosynthesis under drought and salt stress: regulation mechanisms from whole plant to cell. Annals of Botany 103: 551-560. Chou C-H, Kuo Y-L (1986) Allelopathic research of subtropical vegetation in Taiwan. Journal of Chemical Ecology 12: 1431-1448. Chou C-H, Waller GR (1983) Allelochemicals and pheromones. In Allelochemicals and Pheromones. Academia Sinica, Taipei, Taiwan. Contran N, Chessa L, Lubino M, Bellavite D, Roggero PP, Enne G (2013) State-of-the-art of the Jatropha curcas productive chain: From sowing to biodiesel and by-products. Industrial Crops and Products 42: 202-215. Costa N, Erasmo E, Queiroz P, Dornelas D, Dornelas B (2009) Effect of simulated glyphosate drift on the initial growth of physic nut plants. Planta Daninha 27: 1105-1110. Das M, Uppal HS, Singh R, Beri S, Mohan KS, Gupta VC, Adholeya A (2011) Co-composting of physic nut (Jatropha curcas) deoiled cake with rice straw and different animal dung. Bioresource Technology 102: 6541-6546. Demmig‐Adams B, Adams III WW, Barker DH, Logan BA, Bowling DR, Verhoeven AS (1996) Using chlorophyll fluorescence to assess the fraction of absorbed light allocated to thermal dissipation of excess excitation. Physiologia Plantarum 98: 253-264. Demmig B, Winter K, Krüger A, Czygan F-C (1987) Photoinhibition and zeaxanthin formation in intact leaves a possible role of the xanthophyll cycle in the dissipation of excess light energy. Plant Physiology 84: 218-224 Devappa RK, Makkar HP, Becker K (2010) Biodegradation of Jatropha curcas phorbol esters in soil. J Sci Food Agric 90: 2090-2097. Donovan L, Ehleringer J (1994) Water stress and use of summer precipitation in a Great Basin shrub community. Functional Ecology: 289-297. dos Santos CM, Verissimo V, de Lins Wanderley Filho HC, Ferreira VM, da Silva Cavalcante PG, Rolim EV, Endres L (2013) Seasonal variations of photosynthesis, gas exchange, quantum efficiency of photosystem II and biochemical responses of Jatropha curcas L. grown in semi-humid and semi-arid areas subject to water stress. Industrial Crops and Products 41: 203-213. Dou X, Wu G, Huang H, Hou Y, Gu Q, Peng C (2008) Responses of Jatropha curcas L. seedlings to drought stress. Ying Yong Sheng Tai Xue Bao 19(7):1425-30. Eamus D (1999) Ecophysiological traits of deciduous and evergreen woody species in the seasonally dry tropics. Trends in Ecology and Evolution 14: 11-16. Endres L (2007) Daily and seasonal variation of water relationship in sugar apple (Annona squamosa L.) under different irrigation regimes at semi-arid Brazil. Scientia horticulturae 113: 149-154. Espiritu BM (2012) Compost production from Jatropha press cake and compost quality evaluation in Jatropha seedlings. Asia Life Sciences-The Asian International Journal of Life Sciences 21: 149-166. Flexas J, Medrano H (2002) Drought‐inhibition of photosynthesis in C3 plants: stomatal and non‐stomatal limitations revisited. Annals of botany 89: 183-189. Francis G, Edinger R, Becker K (2005) A concept for simultaneous wasteland reclamation, fuel production, and socio-economic development in degraded areas in India: need, potential and perspectives of Jatropha plantations. In Natural Resources Forum 29: 12-24. Fricke K, Vogtmann H (1994) Compost quality: Physical characteristics, nutrient content, heavy metals and organic chemicals. Toxicological and Environmental Chemistry 43: 95-114. Gübitz GM, Mittelbach M, Trabi M (1999) Exploitation of the tropical oil seed plant Jatropha curcas L. Bioresource technology 67: 73-82. Gaind S, Nain L, Patel V (2009) Quality evaluation of co-composted wheat straw, poultry droppings and oil seed cakes. Biodegradation 20: 307-317. Gan Y, Liang C, Hamel C, Cutforth H, Wang H (2011) Strategies for reducing the carbon footprint of field crops for semiarid areas. A review. Agronomy for Sustainable Development 31: 643-656. Gastal F, Lemaire G (2002) N uptake and distribution in crops: an agronomical and ecophysiological perspective. Journal of Experimental Botany 53: 789-799. Ghosh A, Patolia J, Chaudhary D, Chikara J, Rao S, Kumar D, Boricha G, Zala A (2007) Response of Jatropha curcas under different spacing to Jatropha de-oiled cake. In Expert seminar on Jatropha curcas L. Agronomy and Genetics, 26-28. Ghosh L, Singh L (2010) Study of factors influencing vegetative propagation of Jatropha curcas. Indian Forester 136: 1637-1648. Goel G, Makkar HP, Francis G, Becker K (2007) Phorbol esters: structure, biological activity, and toxicity in animals. Int J Toxicol 26: 279-288. Gonçalves KS, São José AR, Cavaliere SD, Martins ISB, Velini ED (2011) Seletividade de herbicidas aplicados em pós-emergência em pinhão manso (Jatropha curcas L.). Revista Brasileira de Herbicidas 10: 110-120. Gour V (2006) Production practices including post harvest management of Jatropha curcas. In Proceedings of the biodiesel conference toward energy independance-Focus of Jatropha, Hyderabad, India, 223-251. Grossl PR, Inskeep WP (1991) Precipitation of dicalcium phosphate dihydrate in the presence of organic acids. Soil Science Society of America Journal 55: 670-675. Gunaseelan VN (2009) Biomass estimates, characteristics, biochemical methane potential, kinetics and energy flow from Jatropha curcus on dry lands. Biomass and Bioenergy 33: 589-596. Heller J (1996) Physic nut, Jatropha curcas L. International Plant Genetic Resources Institute, Rome, Italy. Hsu J-H, Lo S-L (2001) Effect of composting on characterization and leaching of copper, manganese, and zinc from swine manure. Environmental Pollution 114: 119-127. Huante P, Rincón E (1997) Responses to light changes in tropical deciduous woody seedlings with contrasting growth rates. Oecologia 113: 53-66. Inderjit (1996) Plant phenolics in allelopathy. The Botanical Review: 186-202 Jingura RM (2011) Technical options for optimization of production of Jatropha as a biofuel feedstock in arid and semi-arid areas of Zimbabwe. Biomass and Bioenergy 35: 2127-2132. Jones N, Miller JH (1992) Jatropha curcas: A multipurpose species for problematic sites. Land Resources Series-Asia Technical Department, World Bank. Joshi C, Khare SK (2011) Utilization of deoiled Jatropha curcas seed cake for production of xylanase from thermophilic Scytalidium thermophilum. Bioresour Technol 102: 1722-1726. Khalil HPSA, Aprilia NAS, Bhat AH, Jawaid M, Paridah MT, Rudi D (2013) A Jatropha biomass as renewable materials for biocomposites and its applications. Renewable and Sustainable Energy Reviews 22: 667-685. Kochhar S, Singh S, Kochhar V (2008) Effect of auxins and associated biochemical changes during clonal propagation of the biofuel plant—Jatropha curcas. Biomass and Bioenergy 32: 1136-1143. Kruse M, Strandberg M, Strandberg B (2000) Ecological effects of allelopathic plants-a review. Ministry of Environment and Energy National Environmental Research Institut. Kujala TS, Loponen JM, Klika KD, Pihlaja K (2000) Phenolics and Betacyanins in Red Beetroot (Beta v ulgaris) Root: Distribution and Effect of Cold Storage on the Content of Total Phenolics and Three Individual Compounds. Journal of Agricultural and Food Chemistry 48: 5338-5342. Kumar A, Sharma S (2008) An evaluation of multipurpose oil seed crop for industrial uses (Jatropha curcas L.): A review. Industrial Crops and Products 28: 1-10. Kumar A, Sharma S, Mishra S (2010) Influence of arbuscular mycorrhizal (AM) fungi and salinity on seedling growth, solute accumulation, and mycorrhizal dependency of Jatropha curcas L. Journal of Plant Growth Regulation 29: 297-306. Lawlor D, Kontturi M, Young A (1989) Photosynthesis by flag leaves of wheat in relation to protein, ribulose bisphosphate carboxylase activity and nitrogen supply. Journal of Experimental Botany 40: 43-52. Lawlor DW, Tezara W (2009) Causes of decreased photosynthetic rate and metabolic capacity in water-deficient leaf cells: a critical evaluation of mechanisms and integration of processes. Annals of Botany 103: 561-579. Li ZH, Wang Q, Ruan X, Pan CD, Jiang DA (2010) Phenolics and plant allelopathy. Molecules 15: 8933-8952. Liang Y, Chen H, Tang MJ, Yang PF, Shen SH (2007) Responses of Jatropha curcas seedlings to cold stress: photosynthesis‐related proteins and chlorophyll fluorescence characteristics. Physiologia Plantarum 131: 508-517. Ma Y, Chun J, Wang S, Chen F (2013) Allelopathic potential of Jatropha curcas. African Journal of Biotechnology 10: 11932-11942. Macías FA, Castellano D, Molinillo JMG (2000) Search for a Standard Phytotoxic Bioassay for Allelochemicals. Selection of standard target species. Journal of Agricultural and Food Chemistry 48: 2512-2521. Macías FA, Galindo JCG, Molinillo JMG, Castellano D, Velasco RF, Chinchilla D (1999) Developing new herbicide models from allelochemicals. Pesticide Science 55: 662-665. Mahanta N, Gupta A, Khare SK (2008) Production of protease and lipase by solvent tolerant Pseudomonas aeruginosa PseA in solid-state fermentation using Jatropha curcas seed cake as substrate. Bioresour Technol 99: 1729-1735. Makkar H, Becker K, Sporer F, Wink M (1997) Studies on nutritive potential and toxic constituents of different provenances of Jatropha curcas. Journal of Agricultural and Food Chemistry 45: 3152-3157. Mangkoedihardjo S (2008) Jatropha curcas L. for phytoremediation of lead and cadmium polluted soil. World Applied Sciences Journal 4: 519-522. Marschner H, Kirkby E, Cakmak I (1996) Effect of mineral nutritional status on shoot-root partitioning of photoassimilates and cycling of mineral nutrients. Journal of Experimental Botany 47: 1255-1263. Martinez-Herrera J, Siddhuraju P, Francis G, Davila-Ortiz G, Becker K (2006) Chemical composition, toxic/antimetabolic constituents, and effects of different treatments on their levels, in four provenances of Jatropha curcas L. from Mexico. Food Chemistry 96: 80-89. Masaoud M, Ripperger H, Porzel A, Adam G (1995) Flavonol glycosides from Jatropha variegata. Journal für Praktische Chemie/Chemiker-Zeitung 337: 43-45. Maxwell K, Johnson GN (2000) Chlorophyll fluorescence—a practical guide. Journal of Experimental Botany 51: 659-668. Molisch H (1937) Der Einfluss einer Pflanze auf die andere-Allelopathie. Fischer, Jena. Monclus R, Dreyer E, Villar M, Delmotte FM, Delay D, Petit JM, Barbaroux C, Le Thiec D, Bréchet C, Brignolas F (2006) Impact of drought on productivity and water use efficiency in 29 genotypes of Populus deltoides× Populus nigra. New Phytologist 169: 765-777. Muanza D, Euler K, Williams L, Newman D (1995) Screening for antitumor and anti-HIV activities of nine medicinal plants from Zaire. International Journal of Pharmacognosy 33: 98-106. Mujumdar A, Misar A (2004) Anti-inflammatory activity of Jatropha curcas roots in mice and rats. Journal of Ethnopharmacology 90: 11-15. Muller CH (1966) The role of chemical inhibition (allelopathy) in vegetational composition. Bulletin of the Torrey Botanical Club 93: 332-351. Munné-Bosch S, Alegre L (2000) Changes in carotenoids, tocopherols and diterpenes during drought and recovery, and the biological significance of chlorophyll loss in Rosmarinus officinalis plants. Planta 210: 925-931. Netto AT, Campostrini E, de Oliveira JG, Bressan-Smith RE (2005) Photosynthetic pigments, nitrogen, chlorophyll a fluorescence and SPAD-502 readings in coffee leaves. Scientia Horticulturae 104: 199-209. Oliver RJ, Finch JW, Taylor G (2009) Second generation bioenergy crops and climate change: a review of the effects of elevated atmospheric CO2 and drought on water use and the implications for yield. GCB Bioenergy 1: 97-114. Oskoueian E, Abdullah N, Ahmad S, Saad WZ, Omar AR, Ho YW (2011) Bioactive compounds and biological activities of Jatropha curcas L. kernel meal extract. International Journal of Molecular Sciences 12: 5955-5970. Pandey VC, Singh K, Singh JS, Kumar A, Singh B, Singh RP (2012) Jatropha curcas: A potential biofuel plant for sustainable environmental development. Renewable and Sustainable Energy Reviews 16: 2870-2883. Paredes C, Roig A, Bernal M, Sánchez-Monedero M, Cegarra J (2000) Evolution of organic matter and nitrogen during co-composting of olive mill wastewater with solid organic wastes. Biology and Fertility of Soils 32: 222-227. Patel D, Saraf M (2014) Comparative study of different soil amendments and microbes for integrated nutrient management and growth promotion of Jatropha Curcas. Journal of Plant Nutrition 37: 2209-2226. Patterson T, Guy R, Dang Q (1997) Whole-plant nitrogen-and water-relations traits, and their associated trade-offs, in adjacent muskeg and upland boreal spruce species. Oecologia 110: 160-168. Pitzschke A, Forzani C, Hirt H (2006) Reactive oxygen species signaling in plants. Antioxidants and Redox Signaling 8: 1757-1764. Pompelli MF, Barata-Luís R, Vitorino HS, Gonçalves ER, Rolim EV, Santos MG, Almeida-Cortez JS, Ferreira VM, Lemos EE, Endres L (2010) Photosynthesis, photoprotection and antioxidant activity of purging nut under drought deficit and recovery. Biomass and Bioenergy 34: 1207-1215. Qiang W, Xiao R (2007) Autotoxicity of plants and research of coniferous forest autotoxicity. Scientia Silvae Sinicae. Radin JW, Boyer JS (1982) Control of leaf expansion by nitrogen nutrition in sunflower plants role of hydraulic conductivity and turgor. Plant Physiology 69: 771-775. Raj D, Antil RS (2011) Evaluation of maturity and stability parameters of composts prepared from farm wastes. Archives of Agronomy and Soil Science 58: 817-832. Rajaona A, Brueck H, Asch F (2013) Leaf gas exchange characteristics of Jatropha as affected by nitrogen supply, leaf age and atmospheric vapour pressure deficit. Journal of Agronomy and Crop Science 199: 144-153. Reddy AR, Chaitanya KV, Vivekanandan M (2004) Drought-induced responses of photosynthesis and antioxidant metabolism in higher plants. Journal of Plant Physiology 161: 1189-1202. Reis AR, Favarin JL, Malavolta E, Júnior JL, Moraes MF (2009) Photosynthesis, chlorophylls, and SPAD readings in coffee leaves in relation to nitrogen supply. Communications in Soil Science and Plant Analysis 40: 1512-1528. Rejila S, Vijayakumar N (2011) Allelopathic effect of Jatropha curcas on selected intercropping plants (green chilli and sesame). Journal of Phytology 3: 1-3. Rice EL (2012) Allelopathy. Academic Press,Inc. Florida,USA. Sabandar CW, Ahmat N, Jaafar FM, Sahidin I (2013) Medicinal property, phytochemistry and pharmacology of several Jatropha species (Euphorbiaceae): A review. Phytochemistry 85: 7-29. Sahoo NK, Kumar A, Sharma S, Naik S (2009) Interaction of Jatropha curcas plantation with ecosystem. Proceedings of World Academy of Science: Engineering and Technolog 51: 666-671. Salih N, Ågren GI, Hallbäcken L (2005) Modeling response of N addition on C and N allocation in scandinavian Norway spruce stands. Ecosystems 8: 373-381. Severino LS, Lima RLS, Lucena AMA, Freire MAO, Sampaio LR, Veras RP, Medeiros KAAL, Sofiatti V, Arriel NHC (2011) Propagation by stem cuttings and root system structure of Jatropha curcas. Biomass and Bioenergy 35: 3160-3166. Sharma D, Pandey A (2009) Use of Jatropha curcas hull biomass for bioactive compost production. Biomass and Bioenergy 33: 159-162. Silva Ed, Ribeiro R, Ferreira-Silva S, Viégas R, Silveira J (2010) Comparative effects of salinity and water stress on photosynthesis, water relations and growth of Jatropha curcas plants. Journal of Arid Environments 74: 1130-1137. Silva EN, Ferreira-Silva SL, Fontenele AdV, Ribeiro RV, Viégas RA, Silveira JAG (2010a) Photosynthetic changes and protective mechanisms against oxidative damage subjected to isolated and combined drought and heat stresses in Jatropha curcas plants. Journal of Plant Physiology 167: 1157-1164. Silva EN, Ferreira-Silva SL, Viégas RA, Silveira JAG (2010b) The role of organic and inorganic solutes in the osmotic adjustment of drought-stressed Jatropha curcas plants. Environmental and Experimental Botany 69: 279-285. Srinophakun P, Titapiwatanakun B, Sooksathan I, Punsuvon V (2011) Prospect of deoiled Jatropha curcas seedcake as fertilizer for vegetables crops – A case study. Journal of Agricultural Science 4: 211-226. Torres Netto A, Campostrini E, Oliveira JGd, Yamanishi OK (2002) Portable chlorophyll meter for the quantification of photosynthetic pigments, nitrogen and the possible use for assessment of the photochemical process in Carica papaya L. Brazilian Journal of Plant Physiology 14: 203-210. Wang J, Wu Y, Wang Q, Peng Y, Pan K, Luo P, Wu N (2009) Allelopathic effects of Jatropha curcas on marigold (Tagetes erecta L.). Allelopathy Journal 24: 123-130. Wever D-AZ, Heeres HJ, Broekhuis AA (2012) Characterization of Physic nut (Jatropha curcas L.) shells. Biomass and Bioenergy 37: 177-187. Wu F, Bao W, Li F, Wu N (2008) Effects of drought stress and N supply on the growth, biomass partitioning and water-use efficiency of Sophora davidii seedlings. Environmental and Experimental Botany 63: 248-255. Yadav SK, Juwarkar AA, Kumar GP, Thawale PR, Singh SK, Chakrabarti T (2009) Bioaccumulation and phyto-translocation of arsenic, chromium and zinc by Jatropha curcas L.: impact of dairy sludge and biofertilizer. Bioresource Technology 100: 4616-4622. Yang C-M, Chang F, Lin S-J, Chou C-H (2004) Effects of three allelopathic phenolics on chlorophyll accumulation of rice (Oryza sativa) seedlings: II. Stimulation of consumption-orientation. Botanical Bulletin of Academia Sinica 43: 299-304. Yin C, Pang X, Chen K, Gong R, Xu G, Wang X (2012) The water adaptability of Jatropha curcas is modulated by soil nitrogen availability. Biomass and Bioenergy 47: 71-81. Yong JWH, Ng YF, Tan SN, & Chew, A. Y. L. (2010) Effect of fertilizer application on photosynthesis and oil yield of Jatropha curcas L. Photosynthetica 48: 208-218. Yu D, Kim S, Lee H (2009) Stomatal and non-stomatal limitations to photosynthesis in field-grown grapevine cultivars. Biologia Plantarum 53: 133-137. Zeng RS, Luo SM, Shi YH, Shi MB, Tu CY (2001) Physiological and biochemical mechanism of allelopathy of secalonic acid F on higher plants. Agronomy Journal 93: 72-79. Zheng Y-L, Feng Y-L, Lei Y-B, Yang C-Y (2009) Different photosynthetic responses to night chilling among twelve populations of Jatropha curcas. Photosynthetica 47: 559-566. | |
dc.identifier.uri | http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/53002 | - |
dc.description.abstract | 痲瘋樹 (Jatropha curcas L.) 廣泛分布於熱帶及亞熱帶地區,對土壤及環境適應性高,其種子油脂含量高,可作為生質柴油替代燃料。痲瘋樹生長在貧脊的環境,不與糧食作物爭地,植株生質量高,適合作為植生復育,也是天然有機碳庫。煉製的生質柴油,產生較低的環境污染,並且將種籽榨油過後之廢棄產物,作為堆肥,可達到農業零廢棄物目的。
本研究利用種籽榨油過後之籽粕 (Seed cake) 、果殼 (Hull) 及每年修剪痲瘋樹之莖桿木屑 (Sawdust) ,作為堆肥主要材料,經過室內及室外醱酵方式,測其腐熟度。痲瘋樹幼苗分別施加不同等級的籽粕堆肥與化學肥料進行比較試驗,調查痲瘋樹生育狀況與測量光合作用效率,評估堆肥之效益,並檢定籽粕堆肥是否具有相剋潛勢。 結果顯示,化學肥料高氮素等級下,雖然有高葉綠素含量指數,因氣孔導度的降低,沒有顯著提高光合作用能力。而痲瘋樹籽粕堆肥於高氮素等級,光合作用參數Pn (Net CO2 assimilation rate) 、Ci (Intercellular CO2 concentration) 、gs (Stomatal conductance) 才有提升,顯示痲瘋樹籽粕堆肥雖可提供營養元素供幼苗生長使用,但仍需要較長期之分解。於堆肥處理下的葉綠素螢光非光化學消散 (Non-photochemical quenching, NPQ) 增加,有助於痲瘋樹幼株在遭遇環境逆境時啟動光保護機制。在生物檢定 (Bioassay) 之結果顯示,室內醱酵較室外醱酵處理組,有明顯抑制種子胚根、胚軸生長的情形;而總酚含量與生物檢定也有相似的結果,推論醱酵腐熟度較完全的痲瘋樹籽粕堆肥,其相剋潛勢降低,而減少對栽培作物之生育影響。 | zh_TW |
dc.description.abstract | Jatropha curcas is widely distributed in tropical and subtropical regions with the high adaptability in soil and environment. The seeds with high oil content could be converted into the biodiesel as an alternative fuel. It can grow in barren soil and not compete with food crops. With high biomass production, it is suitable for phytoremediation as a carbon sink. The biodiesel produced less environmental pollution. The waste products of seeds after oil extraction as manures can also achieve zero waste agriculture purposes.
After the seeds were crushed, waste productions were produced, like seed cake, hull and the annual pruning of the stems, are the main materials of compost. Measure its maturity after indoor and outdoor fermentation. Jatropha seedlings were applied different levels of seed cake compost and chemical fertilizer to perform a comparison test. Investigate Jatropha curcas growth parameters and photosynthesis rate to assess the effectiveness of seed cake compost, and test whether the compost has allelopathic potential. The results showed that the chemical fertilizer applied high nitrogen level didn’t significantly increase photosynthesis as lower stomatal conductance though it has the high chlorophyll index. Moreover, Jatropha curcas seed cake compost must apply to high nitrogen levels to raise photosynthesis Pn (Net CO2 assimilation rate) 、Ci (Intercellular CO2 concentration) 、gs (Stomatal conductance) . It indicates that Jatropha curcas seed cake compost provides nutrients for seedling growth, however still need more long-term decompose. In compost treatment, the chlorophyll fluorescence non-photochemical quenching increases to induce light protection help relieve environmental stress. According to bioassay results, the indoor fermentation compared to outdoor fermentation treatment, significantly inhibited the root and hypocotyl growth. Similar results were obtained with the total phenolic content. Inference that more complete fermentation maturity which reduces the allelopathic potential, will not impact on fertility of cultivated crops. | en |
dc.description.provenance | Made available in DSpace on 2021-06-15T16:38:37Z (GMT). No. of bitstreams: 1 ntu-104-R02621112-1.pdf: 1933610 bytes, checksum: b3b7352f19ba4f10b3e6bd7b7ac2a8a0 (MD5) Previous issue date: 2015 | en |
dc.description.tableofcontents | 目錄
誌謝 i 摘要 ii Abstract iii 目錄 v 圖目錄 viii 表目錄 ix 第一章、前言 1 一、痲瘋樹介紹 1 (一) 痲瘋樹生物學特徵 1 (二) 痲瘋樹生長環境條件 1 (三) 痲瘋樹栽培管理 2 二、痲瘋樹發展 4 (一) 種植痲瘋樹對環境的效益 4 (二) 痲瘋樹多元應用 5 (三) 痲瘋樹籽粕 5 三、相剋作用 6 (一) 痲瘋樹相剋作用 7 (二) 實施農林制度的可能性 7 第二章、材料與方法 9 一、植物試驗材料 9 二、痲瘋樹籽粕堆肥 9 三、試驗材料種植與處理 10 四、痲瘋樹籽粕之相剋潛勢 10 (一) 種子生物檢定 10 (二) 總酚含量測定 11 五、痲瘋樹生育調查 12 (一) 試驗相關調查分析法 12 (二) 乾物重測量 12 六、氣體交換速率與葉綠素螢光參數測定 13 第三章、結果 14 一、籽粕堆肥處理組合之理化性質 14 二、籽粕堆肥之相剋潛勢 15 (一) 種子生物檢定 15 (二) 總酚含量 15 三、籽粕堆肥對痲瘋樹生育之影響 16 (一) 試驗相關調查分析法 16 (二) 乾物重測量 18 四、光合作用氣體交換及葉綠素螢光參數之影響 20 (一) 光合作用氣體交換參數 21 (二) 葉綠素螢光參數 23 第四章、討論 26 一、籽粕堆肥物理化性質探討 26 二、籽粕堆肥之相剋潛勢 27 三、籽粕堆肥對痲瘋樹生育之影響 29 (一) 試驗相關調查分析法 29 (二) 乾物重結果 30 四、光合作用氣體交換及葉綠素螢光參數之影響 31 (一) 光合作用氣體交換之影響 31 (二) 葉綠素螢光參數之影響 33 第五章、結論與未來展望 35 第六章、參考文獻 36 圖目錄 圖1、痲瘋樹籽粕堆肥堆置過程。 46 圖2、痲瘋樹籽粕堆肥水粗萃取液之總酚含量。 50 圖3、不同肥料處理90天後痲瘋樹莖葉乾物重。 60 圖4、不同肥料處理90天後痲瘋樹根乾物重。 61 圖5、不同肥料處理90天後痲瘋樹根冠比值。 62 圖6、不同肥料處理90天後痲瘋樹總乾物重。 63 圖7、不同肥料處理對痲瘋樹淨同化速率 (Pn) 之影響。 64 圖8、不同肥料處理對痲瘋樹細胞間隙CO2濃度 (Ci) 之影響。 65 圖9、不同肥料處理對痲瘋樹氣孔導度 (gs) 之影響。 66 圖10、不同肥料處理對痲瘋樹蒸散速率 (E) 之影響。 67 圖11、不同肥料處理對痲瘋樹羧化作用效率 (CE) 之影響。 68 圖12、不同肥料處理對痲瘋樹水分利用效率 (WUE) 之影響。 69 圖13、不同肥料處理對痲瘋樹最大光化學潛能 (Fv/Fm) 之影響。 70 圖14、不同肥料處理對痲瘋樹PSII實際光量子效能 (ΦPSII) 之影響。 71 圖15、不同肥料處理對痲瘋樹PSII 相對電子傳遞速率 (ETR) 之影響。 72 圖16、不同肥料處理對痲瘋樹PSII光化學消散 (qP) 之影響。 73 圖17、不同肥料處理對痲瘋樹PSII非光化學消散 (NPQ 或 qN) 之影響。 74 表目錄 表1、不同肥料處理組合。 45 表2、痲瘋樹籽粕堆肥處理組合之理化性質。 47 表3、痲瘋樹籽粕堆肥處理組合之理化性質。 47 表4、一般堆肥之有害成分限量。 47 表5、不同濃度痲瘋樹籽粕粗堆肥萃取液對黑麥草種子發芽之影響。 48 表6、不同濃度痲瘋樹籽粕堆肥粗萃取液對小麥種子發芽之影響。 49 表7、痲瘋樹實生苗在不同肥料處理下30天、60天及90天之株高。 51 表8、痲瘋樹扦插苗在不同肥料處理下30天、60天及90天之株高。 52 表9、痲瘋樹實生苗在不不同肥料處理下30天、60天及90天之莖徑。 53 表10、痲瘋樹扦插苗在不同肥料處理下30天、60天及90天之莖徑。 54 表11、痲瘋樹實生苗在不同肥料處理下30天、60天及90天之葉數。 55 表12、痲瘋樹扦插苗在不同肥料處理下30天、60天及90天之葉數。 56 表13、痲瘋樹實生苗在不同肥料處理下30天、60天及90天之葉綠素含量指數 (SPAD) 。 57 表14、痲瘋樹扦插苗在不同肥料處理下30天、60天及90天之葉綠素含量指數 (SPAD) 。 58 表15、堆肥物理化性質與痲瘋樹生長狀況之相關係數分析。 59 | |
dc.language.iso | zh-TW | |
dc.title | 痲瘋樹籽粕對其生育之影響 | zh_TW |
dc.title | Jatropha seed cake effects the growth of Jatropha curcas | en |
dc.type | Thesis | |
dc.date.schoolyear | 103-2 | |
dc.description.degree | 碩士 | |
dc.contributor.coadvisor | 楊棋明(Chi-Ming Yang) | |
dc.contributor.oralexamcommittee | 許明晃,楊志維,黃盟元 | |
dc.subject.keyword | 生物檢定,非光化學消散,相剋潛勢,堆肥,痲瘋樹籽粕, | zh_TW |
dc.subject.keyword | bioassay,non-photochemical quenching,allelopathic potential,compost,Jatropha curcas seed cake., | en |
dc.relation.page | 74 | |
dc.rights.note | 有償授權 | |
dc.date.accepted | 2015-08-12 | |
dc.contributor.author-college | 生物資源暨農學院 | zh_TW |
dc.contributor.author-dept | 農藝學研究所 | zh_TW |
顯示於系所單位: | 農藝學系 |
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