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研究生: 林延壕
Lin, Yen-Hao
論文名稱: 單核錳金屬超氧錯合物:合成、鑑定及其反應性
Mononuclear Manganese(III) Superoxo Complexes: Synthesis, Characterization and Reactivity
指導教授: 李位仁
Lee, Way-Zen
學位類別: 博士
Doctor
系所名稱: 化學系
Department of Chemistry
論文出版年: 2020
畢業學年度: 108
語文別: 中文
論文頁數: 144
中文關鍵詞: 氧氣活化金屬超氧化合物反應性三價錳超氧化物三價錳金屬過氧氫化物四價錳金屬過氧氫化物
英文關鍵詞: oxygen activation, metal-superoxo reactivity, MnIII-superoxo, MnIII-hydroperoxo, MnIV-hydroperoxo
DOI URL: http://doi.org/10.6345/NTNU202000745
論文種類: 學術論文
相關次數: 點閱:127下載:0
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  • 相較於含鐵金屬仿生錯合物,以含錳金屬仿生錯合物進行氧氣活化的反應是較少被科學家拿來進行探討。本研究使用三氮二氧配位基 (H2BDPP和H2BDPBrP)。與二價錳金屬離子進行錯合反應,分別形成MnII(BDPP) (1) 和MnII(BDPBrP) (2)。在−80 °C下加入氧氣會分別形成MnIII(BDPP)(O2•) (3) 和MnIII(BDPP)(O2•) (4),以UV-Vis、rRaman和EPR光譜,可鑑定其為錳超氧錯合物,且其自旋組態為S = 3/2。錯合物3和4也可以與TEMPO-H進行氫原子轉移反應生成MnIII(BDPP)(OOH) (5)和MnIII(BDPBrP)(OOH) (6),由EPR光譜可以得知其自旋組態為S = 2。除此之外,錯合物 [MnIII(BDPP)(H2O)](OTf) (7)和 [MnIII(BDPP)(H2O)](OTf) (8)加入H2O2/TEA (2:1)也可形成錯合物5和6。錯合物4與2-phenylpropinaldehyde (2-PPA) 進行親核反應,可以生成產物acetophenone。錯合物4在−120 °C與一當量的trifluoroacetic acid (TFA) 反應會形成 [MnIV(BDPBrP)(OOH)]+ (9),可以UV-Vis、rRaman和EPR光譜鑑定。錯合物9也可以加入一當量的TEA或DBU進行去質子化轉變回錯合物 (4)。由MnIII(BDPBrP)(OOH) (6) 低溫循環伏安法實驗可以得到quasi-reversible的訊號,其還原電位為0.19 V (v.s. Fc/Fc+),並且可以藉由氧化劑magic blue氧化生成錯合物9,錯合物9也可以藉由還原劑decamethylferrcene還原為錯合物6。由錯合物6的還原電位0.19 V和錯合物9的pKa = 12.5 ~ 11.1求出錯合物6中OO-H的鍵能為85.6 ~ 87.5 kcal/mol。將路易酸的金屬離子Sc(OTf)3和Zn(OTf)2加入錯合物4會進行metal-coupled electron-transfer反應形成 [MnIVBDPBrP(OO)(Sc(OTf)n)](3−n)+ (10) 和[MnIVBDPBrP(OO)(Zn(OTf)n)](2−n)+ (11)。但加入較弱的路易酸金屬離子Ca(OTf)2卻不會進行metal-coupled electron-transfer。藉由以上的探討,可以更進一步的了解三價錳超氧化物的反應特性。

    Comparing to biomimetic Fe-containing complexes, the biomimetic Mn-containing complexes invented for dioxygen activation is much less explored. In this study, two ligands, H2BDPP and H2BDPBrP were employed to react with MnII ion for the preparation of MnII(BDPP) (1) and MnII(BDPBrP) (2). Both MnII complexes were reacted with O2 at −80 °C to form MnIII–superoxo intermediates MnIII(BDPP)(O2•) (3) and MnIII(BDPBrP)(O2•) (4) characterized by UV-Vis, rRaman and EPR spectroscopy. The spin state of 3 and 4 was 3/2 with a high-spin MnIII center (SMn = 2) antiferromagnetically coupled with a superoxo radical ligand (SOO• = 1/2). Complexes 3 and 4 could perform hydrogen atom abstraction towards TEMPOH at −90 °C to form MnIII(BDPP)(OOH) (5) and MnIII(BDPBrP)(OOH) (6) characracterized by UV-Vis and EPR spectroscopy. The spin state (S = 2) of 5 and 6 is comfirmed by parallel-mode EPR spectroscopy. Besides, Complexes 5 and 6 can also be synthesized by the reactions of [MnIII(BDPP)(H2O)]OTf (7) and [MnIII(BDPBrP)(H2O)]OTf (8) with H2O2/TEA (2:1). Noteworthily, complex 4 is capable of reacting with 2-PPA at −80 °C to produce acetophenone. Intrestingly, complex 4 treated with trifluoroacetic acid at −120 °C generated [MnIVBDPBrP(OOH)]+ (9), which can be deprotonated by 1 equiv. of TEA or DBU to reproduce complex 4. Also, reaction of 4 reacted with Sc(OTf)3 or Zn(OTf)2 induced metal-coupled electron-transfer to form dinuclear MnIV/ScIII and MnIV/ZnII briged peroxo complexes [MnIVBDPBrP(OO)(Sc(OTf)n)](3−n)+ (10) and [MnIVBDPBrP(OO)(Zn(OTf)n)](2−n)+ (11). However, complex 4 did not react with the weaker Lewis acid Ca(OTf)2. In addition, cyclic votalmetry of MnIII(BDPBrP)(OOH) (6) was performed to obtain E1/2 = 0.19 V (v.s. Fc/Fc+) at −80 °C. From E1/2 of 6 and pKa of 9 (12.5 ~ 11.1), we can estimated the bond dissociation freee energy of the OO-H bond in 6 was around 85.6 ~ 87.5 kcal/mol. In conclusion, these results can in-depth understand the reactivity of MnIII-superoxo complexes.

    第一章 緒論 1 1.1血基質含鐵酵素 3 1.2非血基質含鐵酵素 6 1.2.1異青黴素N合成酶Isopenicillin N Synthase (IPNS) 6 1.2.2 2-hydroxyethylphosphonate dioxygenase (HEPD) 8 1.2.3 Homoprotocatechuate 2,3-Dioxygenase (Fe-HPCD) 10 1.3非血基質含錳酵素 11 1.3.1 Oxygen Evolving complex 11 1.3.2 homoprotocatechuate 2,3-dioxygenases (Mn-MndD) 14 1.4.含鐵金屬模擬超氧合物 15 1.4.1 ([(TAML)FeIII(O2•)]2− 15 1.4.2 FeIII(BDPP)(O2•) 17 1.4.3 [FeIII(O2•)(LPh)(TpMe2)] 18 1.4.4 [FeIII(S2Me2N3(Pr,Pr))(O2•)] 20 1.5含錳金屬進行氧氣活化之模擬錯合物 22 1.5.1 [MnIII(L)(O2•)(H2O)](PF6)2 22 1.5.2 [MnIII(SMe2N4(6-MeDPEN)]2(trans-μ-1,2-O2)(BPh4)2 23 1.5.3 [MnIIIH3bupa(O2)]− 25 1.6 Metal-superoxo與質子反應性探討 26 1.6.1 [CuII(TMG3tren)(O2•)]+ 與TFA反應 27 1.6.2 [LCuII(O2•)]− 與phenol反應 30 1.6.3 [(Cl)(TMC)CrIII(O2•)]+ 與HOTf反應性 31 1.7 Metal-superoxo與路易酸反應性探討 33 1.7.1 [(Cl)(TMC)CrIII(O2•)]+ 與路易酸反應性 33 第二章 實驗方法 35 2-1.1 實驗儀器 35 2-1.2 實驗藥品 37 2-1.3 實驗條件 40 2-2配位基合成及反應物製備 41 2-2.1配位基 41 2-2.2 TEMPOH/D之製備 42 2-3錯合物製備 43 2-3.1 MnII(BDPP) (1) 43 2-3.2 MnII(BDPBrP) (2) 43 2-3.3 MnIII(BDPP)(O2•) (3) 和 MnIII(BDPBrP)(O2•) (4) 44 2-3.4 MnIII(BDPP)(OOH) (5)和MnIII(BDPBrP)(OOH) (6) 44 2-3.5 [MnIII(BDPP)(H2O)(OTf)] (7)和[MnIII(BDPBrP)(H2O)(OTf)] (8) 45 2-3.6 [MnIV(BDPBrP)(OOH)]+ (9) 45 2-3.7 [MnIV(BDPBrP)(OO)(Sc(OTf)n)](3−n)+ (10) 46 2-3.8 [MnIV(BDPBrP)(OO)(Zn(OTf)n)](2−n)+ (11) 46 2-4 共振拉曼樣品製備 47 2-4.1 MnIII(BDPP)(O2•) (3)和MnIII(BDPBrP)(O2•) (4) rRaman樣品配置 47 2-4.2 [MnIV(BDPBrP)(OOH)]+ (9) rRaman樣品配置 47 2-4.3 [MnIV(BDPBrP)(OO)(Sc(OTf)n)](3−n)+ (10) rRaman樣品配置 48 2-5 EPR樣品製備 50 2-5.1 MnII(BDPP) (1) 和MnII(BDPBrP) (2) EPR樣品配置 50 2-5.2 MnIII(BDPBrP)(O2•) (4) EPR樣品配置 50 2-5.3 MnIII(BDPBrP)(OOH) (6) EPR樣品配置 50 2-5.4 MnIV(BDPBrP)(OOH) (9) EPR樣品配置 51 2-5.5 [MnIV(BDPBrP)(OO)(Sc(OTf)n)](3−n)+ (10) EPR樣品配置 51 2-6 TEMPO定量實驗 52 2-7 H2O2定量實驗 52 2-8 MnIII(BDPBrP)(O2•) (4)與TEMPOH動力學實驗探討 53 2-9 MnIII(BDPBrP)(OOH) (4)氧化還原電位測量 55 第三章 結果與討論 56 3-1.1 MnII(BDPP) (1) 和MnII(BDPBrP) (2) 合成與結構 56 3-1.2 MnII(BDPP) (1) 和MnII(BDPBrP) (2) 循環伏安法 58 3-1.3 MnII(BDPP) (1) 和MnII(BDPBrP) (2) EPR 光譜之探討 60 3-2.1 MnII(BDPP) (1) 和MnII(BDPBrP) (2) 與氧氣反應 62 3-2.2 MnIII(BDPP)(O2•) (3) rRaman 光譜 66 3-2.3 MnIII(BDPBrP)(O2•) (4) rRaman 光譜 67 3-2.4 MnIII(BDPBrP)(O2•) (4) EPR光譜 69 3-3.1 MnIII(BDPP)(O2•) (3) 和MnIII(BDPBrP)(O2•)(4) TEMPOH反應 73 3-3.2 MnIII(BDPP)(OOH) (5) 和MnIII(BDPBrP)(OOH) (6) 與HOTf反應 76 3-3.3 [[MnIII(BDPP)(H2O)](OTf)] (7) 和 [MnIII(BDPBrP)(H2O)](OTf) (8) 與H2O2/TEA反應 80 3-3.4 MnIII(BDPBrP)(OOH) (6) 之EPR 光譜探討 82 3-3.5 MnIII(BDPBrP)(O2•) (4) 與TEMPOH 反應速率探討 84 3-3.6 MnIII(BDPBrP)(O2•) (4) 與2-PPA反應 86 3-3.7 MnIII(BDPBrP)(O2•) (4)與CF3COOH 反應 88 3-3.8 MnIII(BDPBrP)(O2•) (4) 與CF3COOH反應後產物之EPR光譜 91 3-3.9 MnIII(BDPBrP)(O2•) (4) 與CF3COOH反應後產物之rRaman光譜 96 3-3.10 MnIII(BDPBrP)(OOH) (6)氧化反應 98 3-3.11 [MnIV(BDPBrP)(OOH)] (9) 的還原反應 102 3-3.12 [MnIV(BDPBrP)(OOH)]+ (9) 去質子化反應 104 3-3.13 MnIII(BDPBrP)(OOH) (6) 的O-H鍵能計算 108 3-3.14 模擬光合作用釋放氧氣的過程 112 3-3.15 MnIII(BDPBrP)(O2•) (4) 與Sc(OTf)3的反應 117 3-3.16 MnIII(BDPBrP)(O2•) (4) 與Sc(OTf)3反應後產物之EPR光譜 119 3-3.17 MnIII(BDPBrP)(O2•) (4) 與Sc(OTf)3反應後產物rRaman光譜 122 3-3.18 MnIII(BDPBrP)(O2•) (4) 與Zn(OTf)2反應 123 3-3.19 MnIII(BDPBrP)(O2•) (4) 與Ca(OTf)2反應 125 3-3.20 MnIV(BDPBrP)(OOH) (9) 與TEMPOH反應 127 第四章 結論 130 4-1總結 130 4-2未來展望 133 參考文獻 附錄

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