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研究生: 江奕臻
Jiang, Yi-Zhen
論文名稱: 四羧酸配位基金屬有機骨架從無序化到結晶態的快速結構轉變以及微量苯從環己烷中吸附分離應用
Rapid Disorder to Crystalline Transition and Adsorption Separation of Trace Benzene from Cyclohexane of Tetracarboxylate Based Metal-Organic Frameworks
指導教授: 林嘉和
Lin, Chia-Her
口試委員: 林嘉和
Lin, Chia-Her
陳重佑
Chen, Chong-You
蔡振彥
Tsai, Chen-Yen
楊仲準
Yang, Chun-Chuen
口試日期: 2024/06/03
學位類別: 碩士
Master
系所名稱: 化學系
Department of Chemistry
論文出版年: 2024
畢業學年度: 113
語文別: 中文
論文頁數: 146
中文關鍵詞: 金屬有機骨架雙溶劑置換加熱抽真空結晶化微量苯移除
英文關鍵詞: Metal-Organic Frameworks, Two solvent exchange, Heat under vacuum, Crystallization, Trace benzene removal
研究方法: 實驗設計法
DOI URL: http://doi.org/10.6345/NTNU202401948
論文種類: 學術論文
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  • 近年來金屬有機骨架 (Metal-organic frameworks, MOFs) 材料的研究上顯示,結晶化的MOF是由成核、非序化再到結晶化的。由於結晶過程中不同的狀態會影響成核的速率以及結構的網絡,因此了解其中的生長階段對於想要針對特定應用的MOF的合成開發顯得非常重要。然而,MOF由非序化 (Disordered) 轉變到結晶態 (Crystalline) 的過程,並未見過往的研究提出任何機制探討。
    本研究分為兩個部分,第一部份想探討MOF非序化轉變到結晶化的關鍵原因。承續實驗室已經開發的溶劑脫附誘導非序化及缺陷結構,可快速驅動MOF結晶成有序孔洞結構,本研究將往更廣的面向去討論不同四羧酸配位基的MOF—NU-1000(Zr)、NU-901(Zr)以及MFM-300(M) (M=Al、Ga、Sc、Fe),是否也具有類似的結構轉變現象。透過粉末X射線繞射 (PXRD)、場發射電子顯微鏡 (FE-SEM) 和比表面積及孔隙分析儀,本研究證明以雙溶劑交換 (Two solvents exchange, TOSE) 及加熱抽真空 (Heat under vacuum, HEVA)手法處理的產物依然保有與文獻記載相似的MOF結構、形貌及吸附性能。並透過結晶度計算以及自動電位滴定儀的實驗結果分析,證實了MOF晶格從初合成的非序化結構到因溶劑脫附誘發快速結晶化的過程。本研究更進一步大幅縮短了合成的時間,找出MOF能保持高度結晶性最佳的轉換方法。
    第二部分中,本實驗探討了如何在液相環境中將微量苯從環己烷中吸附移除。目前,全球生產的環己烷中約有80 ~ 85 %是透過苯的還原加氫反應獲得的,該反應會產生環己烷和殘留苯的混合物。由於苯具有相當高的毒性,並會對人體產生短期或長期的健康影響,因此生成環己烷時必須先純化,除去未反應的苯。根據目前市面上化學品公司的表明,環己烷的成品通常含有低於50 ppm的苯。本研究選用MFM-300(Sc)及MFM-300(Ga)作為吸附劑,其孔徑大小約為6.5 Å,具有四羧酸配位基與金屬團簇結合形成的通道型結構,可以有效的將苯捕捉在孔洞中,並且產生大量主體客體或客體客體之間的 π - π 電子作用力。本研究透過氣相層析質譜儀 (GC-MS),分析攪拌吸附後環己烷溶液中微量苯的殘留量。結果表明,在苯濃度約為50 ppm左右的環己烷中加入MFM-300(Sc)或是MFM-300(Ga)作為吸附劑,經過七至八次吸附循環後可以有效的降低苯的含量至將近0 ppm。

    In recent years, literature on metal-organic frameworks (MOFs) materials has indicated that the MOFs nucleate through phase separation, condensation, and crystallization. However, in previous studies, no one has investigated the detailed mechanism of MOFs crystallization from disordered intermediate transform to the crystalline state. Here, we selected tetracarboxylate based MOFs, specifically NU-1000(Zr), NU-901(Zr), and MFM-300(M) (M=Al, Ga, Sc, Fe), to investigate their synthesis process with characterization by using techniques such as powder X-ray diffraction (PXRD), field emission electron microscopy (FE-SEM), and nitrogen gas adsorption. The study reveals that the post-activation steps by two solvent exchanges (TOSE) and heating under vacuum (HEVA) are crucial factors driving rapid transformation of disordered MOFs clusters to a crystalline state. Specifically, we indicates that the structural transformations and the reduction in uncoordinated linker ratio at each step through titration experiment. Moreover, we significantly shortens the reaction time, demonstrating that TOSE-HEVA treatments rapidly accelerate MOFs crystallization while maintaining desired properties. With the strong π-π interaction between host and guest from their considerable amount of aromatic ring, tetracarboxylate based MOFs also could be a promising material for capturing benzene. The research show that using MFM-300(Sc) powder as an adsorbent to cyclohexane, which initially contained approximately 50 ppm of benzene, demonstrates an effective reduction of benzene content to 0 ppm after 8 cycles. This reasearch elucidates the key reasons for MOFs crystallization, offers a promising route for efficient MOFs synthesis, and makes MOFs attractive materials for application in trace benzene removal.

    第一章 緒論 1 1-1 前言 1 1-2 MOF結構的演進 4 1-3 MOF缺陷 6 1-4 MOF結晶化現象 9 1-5 MOF的苯與環己烷分離應用 10 1-6 四羧酸MOF介紹 15 1-7 研究動機 32 第二章 實驗與儀器 35 2-1 實驗藥品 35 2-2 儀器機型和測量簡介 40 2-3 結晶度指數 47 2-4 電位酸鹼滴定法 54 2-5 實驗合成方法 57 2-6 MOF材料的鑑定流程 69 第三章 實驗結果與討論 71 3-1 無序化轉為結晶態 71 3-2 結晶化過程中的結構轉變 111 3-3 微量苯從環己烷中吸附分離應用 125 第四章 結論與展望 133 參考文獻 135 附錄 S1

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