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研究生: 張雅帆
Chang, Ya-Fan
論文名稱: 三角雙錐三價銅磷亞胺錯合物之合成機制與取代反應探討
Synthesis Mechanism and Replacement Study of Trigonal Bipyramidal Copper(III) Phosphineimine Complex
指導教授: 李位仁
學位類別: 碩士
Master
系所名稱: 化學系
Department of Chemistry
論文出版年: 2016
畢業學年度: 104
語文別: 中文
論文頁數: 69
中文關鍵詞: 三價銅錯合物三角雙錐構形軸位配位基置換
英文關鍵詞: copper(III) complex, trigonal bipyramidal, axial ligand exchange
DOI URL: https://doi.org/10.6345/NTNU202204529
論文種類: 學術論文
相關次數: 點閱:87下載:1
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  • 三角雙錐構形的三價銅錯合物[PPN][(TMSPS3)CuIII(NCBH3)] (2),可視為是CH3CN配位在三價銅的類似物[PPN][(TMSPS3)CuIII(NCCH3)],經由[PPN][(TMSPS3)CuIII(Cl)] (1) 和氰基硼氫化鈉(NaBH3CN)反應生成。另外,(TMSPS3)CuIII(NH=PPh3) (3) 可藉由錯合物1在THF下加入NaOMe而得,推測其反應機制是由NaOMe先與THF中少量的水產生OH-陰離子,及時生成的OH-陰離子再將[PPN]+打斷,產生O=PPh3以及NH=PPh3,生成的NH=PPh3會配位上三價銅金屬中心形成五配位的錯合物3。經由外加不同配位基(負電荷的N3-和電中性的DABCO)逐量滴定錯合物3,可知反應為1:1的配位基交換,並以UV-vis光譜儀觀測其變化,求得形成[PPN][TMSPS3CuIII(N3)]和TMSPS3CuIII(DABCO)的Keq分別為0.25和0.15,此結果顯示NH=PPh3的鍵結能力比DABCO和N3-強,推測可能與軸位配位基的鹼性及推電子能力有關。

    A trigonal bipyramidal copper(III) complex, [PPN][(TMSPS3)CuIII(NCBH3)] (2), an analogue of [PPN][(TMSPS3)CuIII(NCCH3)], was synthesized from the reaction of [PPN][(TMSPS3)CuIII(Cl)] (1) with sodium cyanoborohydride (NaBH3CN) in THF. Interestingly, complex 1 was converted to (TMSPS3)CuIII(NH=PPh3) (3) in THF as NaOMe was added. The added NaOMe is proposed to react with trace of water in THF solution to produce OH- anion. Then, the in-situ produced OH- anion attacks [PPN]+, and generates O=PPh3 and NH=PPh3. Further, NH=PPh3 coordinates to the copper(III) center to form the five-coordinate copper(III) complex. UV-vis titration of 3 by adding N3- (Keq = 0.25) or DABCO (Keq = 0.15) complies 1:1 ligand exchange in solution. This result demonstrates that the binding ability of NH=PPh3 ligand is strong than that of DABCO and N3-. This finding is related to basicity and donor capacity of the axial ligand.

    目錄 I 圖引索 III 表引索 VI 中文摘要 VII Abstract VIII 第一章 緒論 1 1-1 銅化學研究動機 1 1-2 單核三價銅文獻回顧 4 1-3 P(C6H3-3-SiMe3-2-SH)3配位的金屬錯合物回顧 8 1-4 研究方向 15 第二章 實驗部分 16 2-1實驗儀器及條件 16 2-2配位基之合成及鑑定 19 2-3錯合物之合成 20 2-4軸位配位基滴定實驗 24 第三章 結果與討論 26 3-1 錯合物1、2探討 26 3-1-1錯合物1之合成方法 26 3-1-2錯合物2之合成鑑定 29 3-1-3錯合物2的生成機制及反應性 31 3-2錯合物3探討 35 3-2-1錯合物3合成及探討 35 3-2-2錯合物3生成機制 38 3-2-3錯合物3電化學探討與比較 43 3-3錯合物軸位配位基鍵結能力探討 46 3-3-1錯合物3溶劑效應 46 3-3-2錯合物3軸位配位基取代反應 47 3-3-3含N軸位配位基之鍵結能力探討 50 第四章 結論與展望 53 參考文獻 55 附錄 58

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