氯离子存在下四苯基卟啉合锰的电化学和现场光谱电化学 I: 还原过程

在二氯乙烷溶液中,研究了氯离子存在下四苯基卟啉合锰,(TPP)Mn(III)ClO~4,各步电极氧化还原的过程机理,证明了Mn(II),Mn(III)中心都只有一个Cl^-配位,其结果使锰卟啉中心金属Mn(III)/Mn(II)的半波电位负和多约100mV,测定了Cl^-与Mn(III)中心的配位反应的平衡常数为2.2×10^4.     

细胞色素P-450模拟体系的活性中间体-氧配位铬(V)四苯基卟啉 配合物的分离、 表征和氧化反应

氮气保护下二氯甲烷中铬(III)四苯基卟啉衍生物在-40℃与亚碘酰苯反应,分离得氧配位铬(V)四苯基卟啉配合物:O=Cr(V)TPP(Cl)PhI,O=Cr(V)TPP(N~30PhI,O=Cr(V)TPP(p-CH~3O-C~6H~4O)(1/2)PhI。已经元素分析、可见、红外、顺磁、核磁和质谱法结构表征。这些配合物能氧化苯乙烯,环己醇,环己烯和环己烷,可作为细胞色素P-450模拟体系的活性中间体。     

金属离子与卟啉的嵌入反应动力学研究 4: Cu(II)Tβ-N-EAESPyP^4^+生成反应中的动力学盐效应

在不同离子强度的高氯酸钠水溶液中, 用分光光度法测量自由卟啉H2Ts-n-EAESPyPBr4(简记为H2P^4^+)与Cu(II)离子的配位反应动力学, 探讨高氯酸钠对Cu(II)离子嵌入自由卟啉反应的催化本质。在给定条件下, 高氯酸根与自由卟啉的缔合数n为1; 缔合平衡常数Ko=3.70±0.42dm^3.mol^-^1。配位反应实验动力学方程为d[Cu(II)P^4^+/dt=5.55×10^5γCu^2^+γH2P^4^+γ^8ClO4^-[ClO4^-]^3[Cu^2^+][H2P]总/(1.00+10^2^.^0^2{H^+}+10^4^.^3^6{H^+}^2, 反应的活化能E=53.30kJ.mol^-^1,活化焓变△H≠=50.31kJ.mol^-^1, 活化熵变△S≠=-77.65J.mol^-^1.K^-^1。提出了金属卟啉生成反应中的ClO4^-催化卟啉环变形的反应机理。     

金属离子与卟啉的嵌入反应动力学研究 4: Cu(II)Tβ-N-EAESPyP^4^+生成反应中的动力学盐效应

在不同离子强度的高氯酸钠水溶液中, 用分光光度法测量自由卟啉H2Ts-n-EAESPyPBr4(简记为H2P^4^+)与Cu(II)离子的配位反应动力学, 探讨高氯酸钠对Cu(II)离子嵌入自由卟啉反应的催化本质。在给定条件下, 高氯酸根与自由卟啉的缔合数n为1; 缔合平衡常数Ko=3.70±0.42dm^3.mol^-^1。配位反应实验动力学方程为d[Cu(II)P^4^+/dt=5.55×10^5γCu^2^+γH2P^4^+γ^8ClO4^-[ClO4^-]^3[Cu^2^+][H2P]总/(1.00+10^2^.^0^2{H^+}+10^4^.^3^6{H^+}^2, 反应的活化能E=53.30kJ.mol^-^1,活化焓变△H≠=50.31kJ.mol^-^1, 活化熵变△S≠=-77.65J.mol^-^1.K^-^1。提出了金属卟啉生成反应中的ClO4^-催化卟啉环变形的反应机理。     

硫在疏质子介质中电化学还原机理的研究 II: 第二步氧化还原过程的研究

用电化学方法研究了硫在DMSO溶剂中的第二步氧化还原过程. 该过程在扫速大于200mV/s时表现为简单的电子转移过程; 扫速小于200mV/s时转化为ECE机理. 发现了S8^4^-, S3^2^-, S4^2^-的氧化峰, 峰电位分别为 -1.50, -0.96, -0.60(相对于银参比电极), 对S8^2^-/S8^4^-电对测定了标准电极电位和标准速率常数, 分别是-1.547±0.002V(相对于银参比电极)和3.3×10^-^3cm/s.     

氯离子存在下四苯基卟啉合锰的电化学和现场光谱电化学II. 氧化过程

本文研究了氯离子滴定过程中四苯基卟啉合锰氧化过程的常规循环伏安、薄层循环伏安及现场紫外-可见光谱电化学行为。发现在1摩尔比的Cl^-存在下, 四苯基卟啉合锰经历了Mn(III)/Mn(III)环阳离子自由基及进一步氧化为环两价阳离子的过程, 并伴随有异卟啉生成的后行化学反应, 当2摩尔比的Cl^-存在时, 反应机理转变为Mn(III)/Mn(IV), Mn(IV)/Mn(IV)环阳离子自由基并伴随有异卟啉生成反应的两个氧化步骤。提出了与这一滴定过程相关的氧化还原反应机理。     

尾式金属卟啉配合物的研究IV: 含氮配体与尾式铁(III)卟啉轴向配位反应热力学及其配位模式

用分光光度法研究了咪唑或吡啶类配体与5-[邻-(4-(1-咪唑基)丁氧基)苯基]-10,15,20-三苯基卟啉合铁(III)氯化物[[Fe^I^I^I(ImTPP)]Cl]和5-[对-(4-(3-吡啶氧基)丁氧基)苯基]10,15,20-三苯基卟啉合铁(III)氯化物[[Fe^I^I^I(PyTPP)]Cl]两种尾式铁(III)卟啉的轴向加合作用, 测定了平衡常数、热力学参数及含氮配体的加合分子数。结果表明, [Fe^I^I^I(PyTPP)Cl与[Fe^I^I^I(TPP)]Cl相类似, 均与咪唑、吡啶类配体生成1:2低自旋六配位加合物。含氮配体与[Fe^I^I^I(ImTPP)]Cl的轴向加合反应平衡常数比与{Fe^I^I^I(TPP)]Cl相应的平衡常数大10-10^3倍, 这是因为含氮配体与[Fe^I^I^I(ImTPP)]Cl的轴向配位诱导了尾端咪唑基与配合物中的Fe^I^I^I离子的轴向配位, 这种配位横式增强了含氮配体与Fe^I^I^I离子的键合; 尾端咪唑基与配合物中的Fe^I^I^I离子配位的模式得到了UV-vis、^1H NMR及EPR实验数据的进一步证实。     

尾式金属卟啉配合物的研究IV: 含氮配体与尾式铁(III)卟啉轴向配位反应热力学及其配位模式

用分光光度法研究了咪唑或吡啶类配体与5-[邻-(4-(1-咪唑基)丁氧基)苯基]-10,15,20-三苯基卟啉合铁(III)氯化物[[Fe^I^I^I(ImTPP)]Cl]和5-[对-(4-(3-吡啶氧基)丁氧基)苯基]10,15,20-三苯基卟啉合铁(III)氯化物[[Fe^I^I^I(PyTPP)]Cl]两种尾式铁(III)卟啉的轴向加合作用, 测定了平衡常数、热力学参数及含氮配体的加合分子数。结果表明, [Fe^I^I^I(PyTPP)Cl与[Fe^I^I^I(TPP)]Cl相类似, 均与咪唑、吡啶类配体生成1:2低自旋六配位加合物。含氮配体与[Fe^I^I^I(ImTPP)]Cl的轴向加合反应平衡常数比与{Fe^I^I^I(TPP)]Cl相应的平衡常数大10-10^3倍, 这是因为含氮配体与[Fe^I^I^I(ImTPP)]Cl的轴向配位诱导了尾端咪唑基与配合物中的Fe^I^I^I离子的轴向配位, 这种配位横式增强了含氮配体与Fe^I^I^I离子的键合; 尾端咪唑基与配合物中的Fe^I^I^I离子配位的模式得到了UV-vis、^1H NMR及EPR实验数据的进一步证实。     

氯离子存在下四苯基卟啉合锰的电化学和现场光谱电化学II. 氧化过程

本文研究了氯离子滴定过程中四苯基卟啉合锰氧化过程的常规循环伏安、薄层循环伏安及现场紫外-可见光谱电化学行为。发现在1摩尔比的Cl^-存在下, 四苯基卟啉合锰经历了Mn(III)/Mn(III)环阳离子自由基及进一步氧化为环两价阳离子的过程, 并伴随有异卟啉生成的后行化学反应, 当2摩尔比的Cl^-存在时, 反应机理转变为Mn(III)/Mn(IV), Mn(IV)/Mn(IV)环阳离子自由基并伴随有异卟啉生成反应的两个氧化步骤。提出了与这一滴定过程相关的氧化还原反应机理。     

trans-[(en)~2(NO~2)Co(O~2CC~5H~5N)]^2^+/Fe(Ⅱ)间电子转移反应动力学及机理研究

合成了新型Co(Ⅲ)配合物trans-[(en)~2(NO~2)Co(O~2CC~5H~5N)](ClO~4)~2, 并通过紫外可见光谱、红外光谱、元素分析和X射线单晶衍射分析进行了表征。同时分别以[Fe(CN)~6]^4^-和[Fe(CN)~5(H~2O)]^3^-作为还原剂, 考察了该配合物被还原的反应动力学行为。结果表明两反应体系分别按外配位界机理和内配位界机理进行电子传递。在25℃, Ⅰ=0.5mol·L^-^1,trans-[(en)~2(NO~2)Co(O~2CC~5H~5N)]^2^+/[Fe(CN)~6]^4^-反应体系的前驱配合物离子对形成常数Q~i~p=29mol^-^1·L, 电子转移速率常数k~e~t=2.4×10^-^4s^-^1,电子转移过程的活化焓△H^≠~e~t和活化熵△S^≠~e~t分别为1.2×10^2kJ·mol^-^1和5.0×10^2J·mol^-^1·K^-^1。在40℃, pH=8.0, Ⅰ=0.1mol·L^-^1,trans-[(en)~2(NO~2)Co(O~2CC~5H~4N)]^2^+/[Fe(CN)~5(H~2O)]^3^-反应体系前驱双核配合物分子内电子转移速率常数为7.0×10^-^5s^-^1。最后讨论了分子轨道对称性, 两金属中心氧化还原电势差等因素对电子转移速率的影响。     

Cobalt(II) and cobalt(III) complexes of thioether-containing hexadentate pyrazine amide ligands: C-S bond cleavage and cyclometallation reaction

Anaerobic reaction of Co(O2CMe)2.4H2O with the thioether-containing acyclic pyrazine amide hexadentate ligand 1,4-bis[o-(pyrazine-2-carboxamidophenyl)]-1,4-dithiobutane (H2L1) (-CH2CH2- spacer between the two pyrazine amide tridentate coordination units) furnishes [CoII(L1)].MeOH (1a) having CoN2(pyrazine)N'2(amide)S2(thioether) coordination. It exhibits an eight-line EPR spectrum, attesting to a low-spin (S = 1/2) state of CoII. A similar reaction in air, however, furnishes [CoIII(L3a)(L3b)].2MeOH (2a) (S = 0), resulting from a C-S bond cleavage reaction triggered by an acetate ion as a base, having CoN2(pyrazine)N'2(amide)S(thioether)S'(thiolate) coordination. On the other hand, the reaction of Co(O2CMe)2.4H2O with 1,4-bis[o-(pyrazine-2-carboxamidophenyl)]-1,5-dithiopentane (H2) (-CH2CH2CH2- spacer between the two pyrazine amide tridentate coordination units) in air affords a cobalt(II) complex [CoII(L2)].MeOH (1b.MeOH) (S = 1/2); its structurally characterized variety has the composition 1b.C6H6. Interestingly, 1b.MeOH undergoes facile metal-centred oxidation by aerial O2-H2O2-[Fe(eta5-C5H5)2][PF6], which led to the isolation of the corresponding cobalt(iii) complex [CoIII(L2)][ClO4] (2b). When treated with methanolic KOH, 2b affords a low-spin (S = 0) organocobalt(III) complex [Co(III)((L2')] (3). Structures of all complexes, except 1a, have been authenticated by X-ray crystallography. A five-membered chelate-ring forming ligand L1(2-) effects C-S bond cleavage and a six-membered chelate-ring forming ligand L2(2-) gives rise to Co-C bond formation, in cobalt(III)-coordinated thioether functions due to alpha C-H bond activation by the base. A rationale has been provided for the observed difference in the reactivity properties. The spectroscopic properties of the complexes have also been investigated. Cyclic voltammetry experiments in MeCN-CH2Cl2 reveal facile metal-centred reversible-to-quasireversible CoIV-CoIII (or a ligand-centred redox process; 2a), CoIII-CoII (1a, 1b.MeOH, 2a, 2b and 3), CoII-CoI (1a, 1b.MeOH, 2aand 2b), and CoI-Co0 (1a, 1b.MeOH and 2b) redox processes.     

Generation and characterization of [(P)M-(X)-Co(TMPA)]n+ assemblies; P = Porphyrinate, M = FeIII and CoIII, X = O2-, OH-, O2(2-), and TMPA = tris(2-pyridylmethyl)amine

With the established chemistry of bridged [(porphyrinate)FeIII-X-CuII(ligand)]n+ [X = O2- (oxo), OH- (hydroxo), O22- (peroxo)] complexes, we investigated the effect of cobalt ion substitution for copper or copper and iron. Thus, in this report, the generation and characterization of new mu-oxo, micro-hydroxo, and micro-peroxo (micro-X) assemblies of [(porphyrinate)MIII-X-CoII/III(TMPA)]n+ assemblies is described, where M = FeIII or CoIII and TMPA = tris(2-pyridylmethyl)amine. The mu-oxo complex [(F8TPP)FeIII-O-CoII(TMPA)]+ (1, F8TPP = tetrakis(2,6-difluorphenyl)porphyrinate) was isolated by an acid-base self-assembly reaction of a 1:1 mixture of (F8TPP)FeIII-OH and [CoII(TMPA)(MeCN)]2+ upon addition of triethylamine. The crystal structure of 1.2C4H10O proved the presence of an unsupported Fe-O-Co moiety; angleFe-O-Co = 171.6 degrees and d(Fe...Co) = 3.58 A. Complex 1 was further characterized by UV-vis (lambdamax = 437 (Soret) and 557 nm), 1H NMR [delta 40.6 (pyrrole-H), 8.8 and 8.7 (m-phenyl-H), 8.0 (p-phenyl-H), 4.4 (PY-4H), 2.6 (PY-3H), 1.0 (PY-5H), -1.1 (PY-6H), and -2.7 (TMPA-CH2-) ppm], electrospray ionization (ESI) and matrix-assisted laser desorption ionization time-of-flight (MALDI-TOF) mass spectrometric methods, Evans method NMR (microeff = 3.1), and superconducting quantum interference device (SQUID) susceptometry (J = -114 cm-1, S = 1). The micro-hydroxo analogue [(F8TPP)FeIII-(OH)-CoII(TMPA)]+ (2) [UV-vis lambdamax = 567 nm; delta 78 ppm (pyrrole-H); Evans NMR microeff = 3.7] was generated by addition of 1 equiv of triflic acid to 1. The protonation is completely reversible, and 1 is regenerated from 2 by addition of triethylamine. While (F8TPP)FeII/[CoII(TMPA)(MeCN)]2+/O2 chemistry does not lead to a stable micro-peroxo species, a dicobalt micro-peroxo complex [(TPP)CoIII-(O22-)-CoIII(TMPA)]2+ (3, TPP = meso-tetraphenylporphyrinate) forms from a reaction of O2 with a 1:1 mixture of the CoII precursor components at -80 degrees C [UV-vis lambdamax = 435 (Soret), 548, and 583 (weak) nm; silent EPR spectrum; diamagnetic NMR spectrum]. The oxygenation/deoxygenation equilibrium is reversible; warming solutions of 3 releases approximately 1 equiv of O2 and the reduced complexes are reformed.     

Synthesis of some novel CoII and CoIII complexes by tribochemical reactions using KI with some derivatives of thiosemicarbazide complexes derived from Girard's T and P

The starting Co(II) complexes of the general formulae, [Co(L1)2]Cl4.4H2O, [Co(L1)Cl2]Cl (L1=N-([(allyl amino)thioxomethyl]hydrazinocarbonylmethyl) trimethylammonium chloride; ATHTC), [Co(L2)Cl]Cl.2H2O.(1/2)EtOH (L2=N-([(ethylamine)thioxomethyl]hydrazinocarbonylmethyl)trimethylammonium chloride; ETHTC) and [Co(L3)Cl2]Cl.2EtOH (L3=N-([(phenylaminomethyl)thioxomethyl]hydrazinocarbonylmethyl)pyridinium chloride; PTHPC), were synthesized by the conventional chemical methods. Tribochemical reactions of the above mentioned CoII complexes obtained by chemical methods with KI afford novel CoII and CoIII complexes with the general formulae [Co(L1')I3.(1/2)EtOH]I, [Co2(L1')I4]I.EtOH, [Co(L2')I2.(3/2)EtOH]I, [Co2(L2')I4(OEt)2(H2O)2]I.(1/2)EtOH and [Co(L3')I2.H2O]I.3H2O. The ligands (L1', L2' and L3') formed by tribochemical reactions are quite similar to these of L1, L2 and L3, except that the ionizable chloride ions in case of L1, L2 and L3 are substituted by iodide ions in (L1', L2' and L3'). The isolated solid CoII and CoIII complexes have been characterized by elemental analyses, conductivities, spectral (IR, UV-vis, 1H NMR) and magnetic measurements. The IR spectra of the starting CoII complexes indicate that both L1 and L3 behave in bidentate manner coordinating via the carbonyl oxygen and NH2 groups, but L2 behaves as a tridentate fashion coordinating via the carbonyl oxygen, azomethine (C=N2) and SH groups with displacement of a hydrogen atom from the latter group. On the other hand, the IR spectra of the iodide CoII and CoIII complexes, synthesized by tribochemical reactions, suggest that L1' behaves only in a bidentate fashion via NH1 and CS groups. L2' behaves either as bidentate ligand through NH1 and CSH with deprotonation from the latter group or as a tetradentate ligand towards two cobalt ions via OH, C=N2, C=N1 and C-SH with displacement of a hydrogen atom from the latter group. Moreover, L3' behaves in a tetradentate ligand, toward two cobalt ions via the carbonyl oxygen, NH2, NH1 and CSH with displacements of a hydrogen atom from the latter group. The spectral and magnetic results suggest a tetrahedral geometry for all CoII complexes prepared by conventional chemical methods. The diamagnetic nature for three of the five iodide complexes, prepared by tribochemical reactions, suggests the oxidation of CoII to CoIII ion and the existence of low spin-octahedral geometry around the CoIII ion. Finally, the results of the rest of the iodide CoII complexes suggest either tetrahedral and/or high-spin octahedral geometry.     

金属卟啉存在下芳醛氧化反应的研究

本文研究了在金属四苯基卟啉[Co(II)TPP,Fe(III)TPPCl,Mn(III)TPPCl,Zn(II)TPP,Cu(II)TP.TPP=四苯基卟啉]存在下,用氧气氧化芳醛的过程.测定了反应体系的吸氧动力学曲线;观察了氧化过程中金属卟啉的可见光谱的变化;研究了底物,金属卟啉在反应体系中的浓度以及溶剂等因素对反应的影响.结果发现,除能可逆键合分子氧的Co(II)TPP外,不具此种功能的Fe(III)TPPCl和Mn(III)TPPCl也能加速芳醛的氧化反应.然而,它们的催化作用是在金属四苯基卟啉与反应过程中积累起来的过酸作用,卟啉环遭到破坏后观察到的,此时可能形成了某种新的催化活性中心.金属卟啉本身对反应起抑制作用,它只是表观上的催化剂,其催化作用看来不应归结为对分子氧的活化.     

F-的轴向配位对(TPP)Co电化学氧化还原的影响研究

钻卟啉的电化学氧化还原行为受轴向配位作用的影响很大［1－5］。通过循环伏安跟踪的阴离子滴定可以细致地考察此影响过程,但至今很少见文献报道［4,5］．我们曾研究了Br-和Cl-存在时,（TPP）Co的电化学氧化行为特征,结果显示不同的卤离子对（TPP）Co电化学氧化还原过程的影响程度有相当大的差别［6,7］．本文以循环伏安跟踪的F-滴定和光谱电化学方法研究了F-的轴向配位效应对（TPP）Co在1,2一二氯乙烷中电化学氧化还原过程的影响．1试剂与仪器1,2一二氯乙烷（DCE,北京化工厂,分析纯）,在CaH。上分馏纯化后使用,四丁基高…     

硫在疏质子介质中电化学还原机理的研究 I: 第一步氧化还原过程的研究

本文用电化学方法研究了硫在DMSO溶剂中第一步氧化还原过程的机理, 发现这个过程不是一个简单的双电子过程, 提出了更为合理的EEC机理, 数字模拟也表明该机理是可能的, 并从2.5次微分谱上发现了S6(II)的氧化峰, 其峰电位为-0.29V(相对于银电极). 还计算了该体系的某些动力学参数值.     

二氢辅酶的电催化氧化: I: α-萘甲酰尼罗蓝修饰电极性能研究

新的电子传递中间体α-萘甲酰尼罗蓝(NNB)能强烈吸附在石墨上以构成修饰电极。在-0.5V至+0.6V(vs. SCE)电位区内, 固定化的NNB表观出相当可逆的氧化还原行为, 总反应中有2个电子和2个质子参加。在pH7.0缓冲溶液中其表面标准电位E°'为-170mV, 表观电子传递常数kg为3s^-^1。NNB对还原辅酶NADH的电化学氧化有明显催化作用, 可使氧化过电位降低550mV。NADH的电催化遵循EC机理, 催化反应步骤为速度决定步骤, 其速度常数为3×10^3dm^3.mol^-^1.s^-^1。NNB在中性和弱碱性介质中的稳定性优于其它电子传递中间体, 是有前途的电催化剂。     

碱性介质中二过碘酸合铜(III)配离子氧化四氢糠醇的动力学及机理

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