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完整後設資料紀錄
DC 欄位 | 值 | 語言 |
---|---|---|
dc.contributor.advisor | 孫岩章 | |
dc.contributor.author | Zoen-Wing Leung | en |
dc.contributor.author | 梁臻穎 | zh_TW |
dc.date.accessioned | 2021-06-17T03:14:58Z | - |
dc.date.available | 2023-07-19 | |
dc.date.copyright | 2018-07-19 | |
dc.date.issued | 2018 | |
dc.date.submitted | 2018-07-09 | |
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dc.identifier.uri | http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/69409 | - |
dc.description.abstract | 一個適合的樹木健康照護(Plant Health Care,PHC)計畫,應該就不同的國家或地區需要就當地氣候環境,以及逆境例如颱風等,並配合其都市樹木的功能加以規劃。臺灣北部為副熱帶季風氣候,每年夏季均受到颱風吹襲影響,故都市樹木之管理必須包含颱風風害預防的考量。
本研究共診斷調查2015-2017三年間3個中度颱風,於臺北地區所造成之樹木風倒狀況。樹木受風倒者共有637筆,共分成四個風倒級別,分別為全倒286筆(44.9%)、莖斷132筆(29.0%)、枝斷146筆(22.9%)以及傾斜20筆(3.1%),當中以榕樹(Ficus microcarpa)最常見,其後依序為垂榕(Ficus benjamina)、台灣欒樹(Koelreuteria elegans)、白千層(Melaleuca leucadendron)、小葉欖仁(Terminalis mantaly H. Perrier)。並嘗試利用3個颱風對樹木造成的風倒級別及最大切風風速與樹木莖斷及枝斷之關聯性作分析,結果皆未能證明颱風強度及最大切風風速對預測樹木風倒災情有指標性作用。後以樹冠寬與風倒級別作分析,發現樹冠寬/胸徑值比值介乎5.00到19.99之間,較容易受風倒影響。同時,樹冠形狀為展開及尖錐形的樹木,立於人行道旁的行道樹,相比其他樹冠形狀及立地位置的樹木,更容易造成風倒。 在臺北地區颱風造成樹木風倒害因的統計及分析中,資料倒分析分成單一害因及複合害因,經3次颱風資訊比較後,害因常見以樹冠過重、受腐朽影響、生長逆境、患有褐根病為主,樹木淺根、處於風場、白蟻蛀食為副。經卡方統計及類別變項交叉分析之勝算比,可知行道樹、樹木淺根、處於生長逆境的樹木遇上風害時傾向發生全倒。在災後三個月及生長季後進行災後調查,有經災後處理的樹木之生長勢恢復能力明顯比沒有經災後處理的樹木為高。同時,目前的災後處理方法使樹木生長勢恢復能力,無論在四個立地位置之中,皆比期望值高。唯盾柱木(Peltophorum pterocarpum)、鐵刀木(Senna siamea)、豔紫荊(Bauhinia x blakeana Dunn.)需要進行災後的結構性修剪。 研究同時關注木材腐朽菌問題,在52個樣本中分離出腐朽菌,利用木質素及纖維素分解酵素分泌能力作篩選,分離出腐朽能力最大的六株腐朽菌。接種到三種樹木的木片上皆有不同程度的外觀及乾重損失,經柯霍氏法則驗證後證實腐朽菌於不同木材中皆具有腐朽能力。為了有效篩選出適用的防治藥劑,實驗利用9種不同作用機制及原理的藥劑以10,000倍稀釋濃度先行篩選,再以5種藥劑各12種濃度加入PDA培養基測試以獲得各藥劑對各腐朽菌的半抑制濃度及半致死濃度。 經研究發現菲克利10%乳劑80 ppm、撲克拉25%水基乳劑40 ppm及普克利25%乳劑90 ppm效果最佳,在田間試驗中即利用上述三種配方在每200平方毫米的木材面積下以50mL藥劑處理腐朽菌,於預防及治療測試上都達到90%以上之防治成效。 | zh_TW |
dc.description.abstract | A flexible Plant Health Care program, PHC, has to consider the difference and extreme climates in countries and cities, such as typhoons, in order to manage the urban trees and maintain their functional contributions. Because of the subtropics monsoon and humid climate, five to six typhoons usually attacked the northern Taiwan every summer. Therefore, typhoon is an essential consideration for urban trees management program in Taipei
A 3-year study was from 2015 to 2017, to diagnose and survey the wind-fallen trees caused by three typhoons with intensities not lower than moderate at Taipei areas. A total of 637 cases of wind-fallen trees were diagnosed and recorded. The fallen trees were separated into 4 tree falling levels, including 286 fully fallen cases (44.90%), 132 trunk broken cases (29.04%), 146 twig broken cases (22.91%), and 20 leaning cases (3.13%). Among 637 cases, the dominant tree species in decreasing series, are Chinese banyan (Ficus microcarpa), Benjamin tree (Ficus benjamina), Taiwan golden-rain tree (Koelreuteria elegans), Cajeput tree(Melaleuca leucadendron) and Madagascar almond (Terminalis mantaly H. Perrier). The study tried to reveal the relationship between trees falling levels as well as numbers of trunk broken or twig broken and the maximum wind speed. Results showed that the maximum wind speed played no significant effect on tree falling level or numbers of trunk broken or twig broken. This study, however, discovered that those trees with canopy-width/DBH ratio between 5.00-19.99, or trees with either open shape or sharp canopy shape, are more easily suffered by typhoons. The study also determined the major and minor causal factors of tree falling. The main causal factors usually are trees with too heavy crowns, infected by wood rot fungi, with environmental stress, or with brown root rot disease. The second causal factors are trees with shallow root systems, growing within strong wind field, or attacked by termites. According to the results of Chi-square test and odd ratio analysis, road side trees, trees with shallow root systems, and trees growing with environmental stress, have higher potential for fully falling during typhoons, other than trunk broken or leaning. The survey of efficacy for post-typhoon tree treatment after 3-months or after the next growth season revealed that the present post-typhoon treatment for wind-fallen trees were effective and beneficial for tree vigor recovering. The observed recovered numbers of trees are more than the expected ones, wherever they are growing in one of 4 planting sites. The survey finally suggested that a structural pruning is necessary for yellow flame tree (Peltophorum pterocarpum), Kassod tree (Cassia siamea), Hong Kong orchid tree (Bauhinia x blakeana Dunn.) after typhoons. The study also focused on the issue of wood rot fungi. After isolating 35 common rot fungi from 52 wind-fallen tree samples, 6 stronger fungi were screened from them by comparing their enzymes activities for lignin and cellulose degradation. Those wood rot fungi were inoculated onto wood chips from 3 tree species for 30 days to determine the weight loss rate caused by the fungi. Results showed that the wood chips showed different level of dry weight loss and different color change. The six selected wood rot fungi can be reisolated and thus fulfilled the rules of Koch’s postulates. In order to find out the most suitable fungicides for wood rot control, a series of experiments were done. Nine fungicides with different action mode or mechanism were chosen and tested each at dilution of 10,000X, to find their mycelium inhibition rates. Then five of them were determined for their half maximum inhibitory and half lethal concentration when each is diluted into 12 serial concentrations in PDA medium, and to test their mycelium inhibition rates against the six wood rot fungi. The study results showed that hexaconazole (10% EC) at 80 ppm, prochloraz (25% EW) at 40 ppm, and propiconazole (25% EC) at 90ppm, are the most effective fungicide formulations for field application. A 50 mL of them were used to spray on maple wood block each for a 200 cm2 wood surface. Results showed that for preventing or curing the wood rot fungi, all three fungicides performed at least a 90% control rate in the field tests. | en |
dc.description.provenance | Made available in DSpace on 2021-06-17T03:14:58Z (GMT). No. of bitstreams: 1 ntu-107-R05645012-1.pdf: 52020766 bytes, checksum: 12089df6bff9f706f270a259275c8bcb (MD5) Previous issue date: 2018 | en |
dc.description.tableofcontents | 目錄
第一章 前言 1 第二章 前人研究 3 一、 颱風風倒樹木調查 3 (一) 臺北市政府針對颱風樹木之救災作業簡介 3 (二) 臺灣過去樹木風倒調查 3 (三) 樹木抗風能力研究 4 1. 樹種對抗風能力之影響 4 2. 樹冠結構對抗風能力之影響 5 3. 枝幹結構對抗風能力之影響 5 4. 根系結構對抗風能力之影響 7 二、 木材腐朽菌簡介 8 三、 木材腐朽菌分離及鑑定 9 (一) 木材腐朽菌纖維素分解酵素分泌能力之測試 10 (二) 木材腐朽菌木質素分解酵素分泌能力之測試 10 (三) 藥劑篩選簡介 11 第三章 材料與方法 13 一、 臺北地區 2015 - 2017 年颱風造成風倒樹木之調查 13 二、 臺北地區颱風造成樹木風倒之級別統計及分析 17 (一) 颱風最大切風風速與樹木莖斷及枝斷之關聯性分析 17 (二) 容易受風災影響都市林樹種之分析 17 (三) 樹冠寬與風倒級別之關聯性分析 17 (四) 樹冠形狀與風倒級別之關聯性分析 18 (五) 樹木立地位置與風倒級別之關聯性分析 18 三、 臺北地區颱風造成樹木風倒之害因統計及分析 19 (一) 單一害因分析 19 (二) 複合害因分析 19 (三) 樹木風倒與主要害因之勝算比 19 四、 颱風風倒後樹木之災後處理及結果之調查 20 (一) 颱風風倒後處理與樹木恢復能力之關聯性 21 (二) 不同立地位置災後處理之效果 21 五、 颱風風倒後木材腐朽菌之分離及鑑定 21 (一) 颱風風倒後木材腐朽菌之分離 21 (二) 木材腐朽菌之纖維素分解酵素分泌能力測試 22 (三) 木材腐朽菌之木質素分解酵素分泌能力測試 22 (四) 木材腐朽菌之形態學鑑定 23 (五) 木材腐朽菌之分子生物學鑑定 23 (六) 六種颱風風倒木材腐朽菌之綜合鑑定 24 (七) 木材腐朽菌之腐朽能力測試 24 六、 颱風風倒木材腐朽菌防治藥劑之篩選及測試 24 (一) 以化學藥劑培養基進行抑制能力之測試 25 (二) 化學藥劑半抑制濃度(IC50)及半致死濃度(LC50)測試 25 (三) 藥劑效力之衰變測試 26 (四) 篩選藥劑進行腐朽菌之預防及治療之噴施 26 1. 篩選藥劑進行腐朽菌之預防性噴施 26 2. 篩選藥劑進行腐朽菌之治療性噴施 27 第四章 結果 28 一、 臺北地區 2015 - 2017 年颱風造成風倒樹木之調查 28 二、 臺北地區颱風造成樹木風倒之級別統計及分析 33 (一) 颱風最大切風風速與樹木莖斷及枝斷之關聯性分析 33 (二) 容易風倒都市林樹種之分析 35 (三) 樹冠寬與風倒級別之關聯性分析 36 (四) 樹冠形狀與風倒級別之關聯性分析 38 (五) 樹木立地位置與風倒級別之關聯性分析 40 三、 臺北地區颱風造成樹木風倒之害因統計及分析 41 (一) 單一害因分析 41 (二) 複合害因分析 43 (三) 樹木風倒與主要害因之勝算比 45 四、 颱風風倒後樹木之災後處理及結果之調查 47 (一) 颱風災後處理與樹木恢復能力之關聯性 47 (二) 不同立地位置災後處理之效果 48 五、 颱風風倒後木材腐朽菌之分離及鑑定 50 (一) 颱風風倒後木材腐朽菌之分離 50 (二) 木材腐朽菌之纖維素分解酵素分泌能力測試 53 (三) 木材腐朽菌之木質素分解酵素分泌能力測試 55 (四) 木材腐朽菌之形態學鑑定 56 (五) 木材腐朽菌之分子生物學鑑定 63 (六) 六種颱風風倒木材腐朽菌之綜合鑑定 66 (七) 木材腐朽菌之腐朽能力測試 67 六、 颱風風倒木材腐朽菌防治藥劑之篩選及測試 72 (一) 以化學藥劑培養基進行抑制能力之測試 72 (二) 化學藥劑半抑制濃度(IC50) 及半致死濃度(LC50)測試 74 (三) 藥劑效力之衰變測試 76 (四) 篩選藥劑進行腐朽菌之預防及治療性之噴施 80 1. 篩選藥劑進行腐朽菌之預防性噴施 80 2. 篩選藥劑進行腐朽菌之治療性噴施 83 第五章 討論 86 一、 臺北地區 2015 - 2017 年颱風造成風倒樹木之調查 86 二、 臺北地區颱風造成樹木風倒之級別統計及分析 86 三、 臺北地區颱風造成樹木風倒之害因統計及分析 88 四、 颱風風倒後樹木之災後處理及結果之調查 89 五、 颱風風倒後木材腐朽菌之分離及鑑定 90 六、 颱風風倒木材腐朽菌防治藥劑之篩選及測試 91 七、 結論及建議 93 參考文獻 94 | |
dc.language.iso | zh-TW | |
dc.title | 颱風造成臺北地區樹木風倒害因及其管理之研究 | zh_TW |
dc.title | Studies on Casual Factors and their Management of Tree Falling by Typhoon at Taipei Areas | en |
dc.type | Thesis | |
dc.date.schoolyear | 106-2 | |
dc.description.degree | 碩士 | |
dc.contributor.oralexamcommittee | 林法勤,林振榮,郭章信 | |
dc.subject.keyword | 風倒影響,風倒害因,風險評估,木材腐朽菌,颱風後處理, | zh_TW |
dc.subject.keyword | wind-fallen trees,Causes of tree failure,Tree risk assessment,Wood rot fungi,Post-typhoon treatments, | en |
dc.relation.page | 100 | |
dc.identifier.doi | 10.6342/NTU201801375 | |
dc.rights.note | 有償授權 | |
dc.date.accepted | 2018-07-10 | |
dc.contributor.author-college | 生物資源暨農學院 | zh_TW |
dc.contributor.author-dept | 植物醫學碩士學位學程 | zh_TW |
顯示於系所單位: | 植物醫學碩士學位學程 |
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