臺灣博碩士論文加值系統

目錄
摘要 I
誌謝 IV
目錄 V
表目錄 VIII
圖目錄 X
第一章 研究緣起與目的
第二章 文獻回顧
2-1 總石油碳氫化合物(含BTEX)介紹
2-1-1 污染物來源
2-1-2 污染物危害性及暴露
2-1-3 國內外土壤污染現況及法規標準
2-2 BTEX污染土壤復育技術
2-2-1 土壤復育技術分類
2-2-2 土壤復育技術介紹
2-2-3 現地化學氧化法及影響因子
2-2-4 氣提後處理技術
2-3金屬催化氧化反應介紹
2-3-1 自由金屬催化反應
2-3-2 複合金屬催化反應
2-3-3 自由基種類及其捕捉劑
2-3-4 催化氧化可能機制
2-4 因子實驗設計及其最佳化
2-4-1 單因子實驗設計及其優缺點
2-4-2 多因子實驗及其優缺點
2-4-3 反應曲面法及其應用時機
2-5 一階反應及擬一階反應
第三章 研究材料與方法
3-1 研究架構與流程
3-2 實驗藥品與材料
3-3 實驗項目及方法
3-3-1 BTEX頂空處理法及內標法
3-3-2各種金屬催化氧化動力學測試
3-3-3各種屬催化氧化反應對於BTEX降解效率
3-3-4各種金屬與H2O2催化氧化反應機理
3-3-5優勢催化劑EDTA-Fe2+/H2O2降解BTEX因子測試
3-3-6金屬催化氧化反應降解BTEX模槽實驗
3-3-7 其他實驗項目(pH、汽油成分分析)
3-4分析設備
3-4-1 氣象層析儀-火焰離子偵測器(GC-FID)
3-4-2 氣象層析質譜儀 (GC-MS)
3-4-3其它設備
3-5 檢量線及品質管制
3-5-1 檢量線建立
3-5-2重複樣本及品質管制
第四章 結果與討論
4-1 各金屬催化氧化反應測定
4-2 各金屬催化氧化反應機制及評估
4-3 最適催化氧化操作及條件
4-3-1 決定催化氧化操作之有效因子
4-3-2 最佳化催化劑及氧化劑之實驗
4-4 金屬催化氧化反應降解BTEX模槽實驗
第五章 結論與建議
第六章 工程應用性
參考文獻

表目錄
表2-1石油產物碳數分布、沸點及用途
表2-2 石油碳氫化合物分類
表2-3 BTEX物理化學性質
表2-4 BTEX對於生物體危害整理
表2-5 台灣土壤有機化合物管制標準
表2-6 台灣石油碳氫化合物土壤污染濃度範圍
表2-7 國際重大土壤污染事件
表2-8土壤污染整治技術方法分類表
表2-9 各種處理方法之優缺點整理
表2-10台灣地區運用土壤及地下水污染整治技術
表2-11不同氧化劑優缺點
表2-12各化學氧化法處理及結果
表2-13 化學氧化法處理氣相有機物整理
表2-14 金屬螯合劑介紹
表2-15 自由基種類及捕捉劑
表2-16 22因子設計
表3-1 藥品資訊表
表3-2 24全因子實驗設計
表3-3 24全因子實驗劑量表
表3-4 23全因子實驗設計
表3-5 23全因子實驗劑量表
表3-6 22全因子實驗設計
表3-7 22全因子實驗劑量表
表3-8 模槽實驗設計-催化劑為因子
表3-9 模槽實驗設計-氧化劑為因子
表3-10 GC-FID分析條件
表3-11 GC-MS 分析條件
表3-12 BTEX檢量線配置表
表3-13 空白BTEX濃度三重複分析
表4-1 Fe2+作為催化劑一階降解模式結果
表4-2 Cu2+作為催化劑一階降解模式結果
表4-3 EDTA-Fe2+作為催化劑一階降解模式結果
表4-4 Hemin作為催化劑一階降解模式結果
表4-5 24全因子低/高水平的因子值
表4-6 23全因子低/高水平的因子值
表4-7 22全因子低/高水平的因子值

圖目錄
圖 2 1 一般常見的SVE系統
圖2-2 生物通氣法處理系統
圖2-3 生物堆法處理系統
圖2-4 空氣注入法搭配氣體抽除法處理系統
圖2-5 植物整治法處理概念
圖2-6 低溫加熱脫附處理系統
圖2-7 現地化學氧化處理示意圖
圖2-8 均相Fenton反應機制意示圖
圖2-9 非均相Fenton反應機制意示圖
圖2-10 氯化血紅素氧化機制
圖3-1 研究架構圖
圖3-2 實驗設計概念圖
圖3-3 實驗室模槽系統設計圖
圖3-4金屬催化氧化反應動力學測試流程圖
圖3-5催化氧化反應對於BTEX降解效率流程圖
圖3-6金屬催化氧化反應機制意示圖
圖3-7 反應曲面法實驗設計
圖3-8系統實驗尾氣分析流程圖
圖3-9 系統實驗活性碳分析流程圖
圖3-10 氣相層析儀-火焰離子偵測器
圖3-11 氣象層析質譜儀
圖3-12 苯檢量線
圖3-13 甲苯檢量線
圖3-14 乙苯檢量線
圖3-15 對-二甲苯檢量線
圖 4-1 Fe2+作為催化劑氧化反應濃度與時間關係圖
圖 4-2 Cu2+作為催化劑氧化反應濃度與時間關係圖
圖 4-3 EDTA-Fe2+作為催化劑氧化反應濃度與時間關係圖
圖 4-4 Hemin作為催化劑氧化反應濃度與時間關係圖
圖4-5 常態隨機分佈圖(EDTA-Fe2+為催化劑使用)
圖4-6 殘留物隨機分佈圖(EDTA-Fe2+為催化劑使用)
圖4-7 擬一階模式模擬結果圖(EDTA-Fe2+為催化劑使用)
圖4-8 實驗組中各金屬催化氧化效率圖
圖4-9 超氧陰離子控制組降解效率圖
圖4-10 氫氧自由基控制組降解效率圖
圖4-11 不同濃度Fe2+降解濃度圖
圖4-12 不同濃度Fe2+降解效率圖
圖4-13 不同濃度EDTA-Fe2+降解濃度圖
圖4-14 不同濃度EDTA-Fe2+降解效率圖
圖4-15 不同濃度Hemin降解濃度圖
圖4-16 不同濃度Hemin降解效率圖
圖4-17 不同濃度氧化劑降解濃度圖
圖4-18 不同濃度氧化劑降解效率圖
圖4-19 24全因子效應分析(因子: EDTA-Fe2+、H2O2、pH、及溫度)
圖4-20 24全因子常態機率分布圖(因子: EDTA-Fe2+、H2O2、pH、及溫度)
圖4-21 23全因子效應分析(因子: EDTA-Fe2+、H2O2及pH)
圖4-22 24全因子常態機率分布圖(因子: EDTA-Fe2+、H2O2及pH)
圖4-23 22全因子效應分析(因子: EDTA-Fe2+、H2O2)
圖4-24 22全因子常態機率分布圖(因子: EDTA-Fe2+、H2O2)
圖4-25 反應曲面法設計
圖4-26 反應曲面法第一階段實驗結果
圖4-27 反應曲面法第二階段實驗結果
圖4-28 反應曲面法第三階段實驗結果
圖4-29 反應曲面法第四階段實驗結果
圖4-30 最佳化反應曲面圖
圖4-31 最佳化反應等高線圖
圖4-32 模槽空白時間濃度變化圖
圖4-33 模槽活性碳only時間濃度變化圖
圖4-34 氧化劑單因子實驗結果(以重量表示)
圖4-35 氧化劑單因子實驗結果(以效率表示)
圖4-36 催化劑單因子實驗結果(以重量表示)
圖4-37 催化劑單因子實驗結果(以效率表示)
圖4-38 系統降解及吸附各污染物效率圖
圖4-39 活性碳重量單因子氧化及吸附效率圖
圖4-40 活性碳單因子實驗尾氣濃度圖(30 g活性碳)
圖4-41 活性碳單因子實驗尾氣濃度圖(40 g活性碳)
圖4-42 活性碳單因子實驗尾氣濃度圖(50 g活性碳)
圖4-43 活性碳單因子實驗尾氣濃度圖(60 g活性碳)
圖6-1 本技術工程示意圖

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