系列Fe4S4簇合物的光谱分析

本文报道了自合成的4种类立方烷型Fe_4S_4簇合物[Et_4N][Fe_4S_4(Et_2dtc)_4]、[Et_4N]_2·[Fe_4S_4(Et_2dtc)_4]、[Et_4N]_3[Fe_4S_4(Et_2dtc)_4]、[Bu_4N]_2[Fe_4S_4(PhS)_4]的UV-Vis和IR光谱数据,对照X光衍射测定结果,依据配体场弱场理论,对各光谱进行了分析和指认。讨论了配离子构型、中心离子氧化态对d-d带和荷迁移带的影响及键长、配位环境等几何因素与振动带的关系。     

双核配合物组合合成Mo_nFe_(4-n)S_4单立方烷簇合物及Mo_2Fe_2S_4(C_4H_8dtc)_6·3.5C_2H_2Cl_4的结构

从含有M Fe(M=Mo,Fe)结构单元的双核配合物Mg(DMF)_6[Fe_2S_2Cl_4]及Mg(DMF)_6[FeCl_2·MoS_4]起始,经不同的组合反应,分别得到Fe_4S_4,MoFe_3S_4及Mo_2Fe_2S_4单立方烷簇合物。讨论了这一反应的某些特点并报道了双桥联六配体的Mo_2Fe_2S_4(C_4H_8dtc)_6的晶体与分子结构。     

[Fe4S4Cl4—n（S2CNEt2）n]^2—（n=0,1,2,4）：原子簇的电子结构研究

用CNDO/2(s,p,d)方法研究了类立方烷系列Fe-S簇合物[Fe_4S_4Cl_4(?)(S_2CNEt_2)_n]~(2-)(n=0,1,2,4)的电子结构。得出[S_2CN(Et)_2]-螯合配位Fe_4S_4~(2+)簇合物中存在两类不同价态铁原子的结论;骨架Fe_4S_4~(2+)中μ_3-S电子是非定域化的,同Mssbauer谱测定结果一致。讨论了簇合物Fe—Fe之间的成键作用、螫合配体的作用和氧化还原性质。     

Fe2S2(SH)4[2-,3-]的从头计算

正确的能级次序应与分子的活性位置一致.实验证实,铁硫蛋白或模型化合物Fe_2S_2(SR)~(2-)及Fe_4S_4(SR)_4~(2-)的活性位置在端基,易于发生多种取代反应,而Fe_2S_2和Fe_4S_4实一般是稳定的.但是,经过电化学还原生成的Fe_2S_2(SR)_4~(3-),却不可逆地二聚化,生成Fe_4S_4(SR)_4~(2-)     

SYNTHESIS AND STRUCTURE OF (Et_4N) [Fe_4S_4 (Et_2NCS_2)_4 ]

<正> INTRODUCTION. The Fe_4S_4 cubane-like clusters have been extensively studied as the model compounds for the active center of the Fe-S proteins in the last fifteen years. Coucouvains et al. have recently reported the syntheses and structures of a few Fe_4S_4 cluster compounds containing R_2NCS_2(R_2dtc) and RS (or Cl) mixed terminal ligands and having [Fe_4S_4]~(2+) core oxi-     

[Fe_4S_3]网兜骨架的红外光谱探索

本文报导了利用陆森黑盐阴离子的相应几何参数和力常数,对网兜骨架[Fe_4S_3]的简正坐标分析,得到了该骨架振动的理论计算频率。以此为根据,针对陆森黑盐系统中的氨合成过程,论证了[Fe_4S_3]网兜骨架一直是存在的,并起着主要固氮作用。     

PENTACOORDINATED IRON-SULFUR COMPLEXES I.SYNTHESIS AND STRUCTURE OF DINUCLEAR COMPLEX [Fe_2(o-SC_6H_4S-S,S')_4](Et_4N)_2

<正> INTRODUCTION. On close investigation of the 'P cluster' of nitrogenase, which is known to consist of Fe_4S_4~(2+) core, scientists have considered that the collective properties are highly suggestive of those being variants of analogue Fe_4S_4~(2+) clusters. Attention has been directed recently to the possibility that 'P cluster' variations may include some or all Fe atoms that are not 4-coordinated as in usual Fe-S analogues but are 5-coordinated.     

钼铁硫簇合物催化乙炔还原活性及其与组成和结构的关系

在25℃和无氧条件下,以KBH_4为还原剂,测定了七种Mo-Fe-S簇合物(Ⅰ.(Et_4N)_4 [Mo_2Fe_2S_(10)]·2CH_3OH,Ⅱ.Mo_2Fe_2S_4(S_2CNEt(?))_5·CH_3CN,Ⅲ.(Bu_4N)_3[Mo_2FeS_3O],Ⅳ.(Et_4N)_3[Mo_2FeS_3O_2],Ⅴ.(Et_4N)_2[MoFeS_4(SCN)_2(OCH_3)_2]·3CH_3OH,Ⅵ.(Et_4N)_3 [Mo_2FeS_3O(OCH_3＇2],Ⅶ.(Et_4N)_4[Mo_2Fe_7S_(12)(SPh)_6]·6CH_3OH),三种Fe-S簇合物(Ⅷ.(Et_4N)_4[Fe_4S_4(S_2CNEt_2＇4],Ⅸ.(Bu_4N)_2[Fe_4S_4(SC(CH_3) 3)4],Ⅹ.(Bu_4N)[Fe_2S_3(SCH_2Ph)_2])和相关化合物的组合体系的催化乙炔还原活性.还在15℃和其它条件不变的情况下,测定了九种(?)由(NH_4)_2MoS_4和FeCl_3组成的不同组分的组合体系的催化乙炔还原活性.对上述实验结果进行了讨论.     

二核Fe/S化合物(Et4N)2[Fe2S2Br4]的合成与结构

标题化合物(Et_4N)_2[Fe_2S_2Br_4](1)在VS_4~(3-)/FeBr_2/imnt~(2-)/Et_4NCI的反应体系中获得,它属于单斜晶系,空间群P2_1/n,主要晶胞参数为:α=0.91193(2)nm,b=1.03874(3)nm,c=1.54360(1)nm,β=105.090(1)°,V=1.41177(5)nm~3,Z=2, ρ=1.778g/cm~3,μ=6.841cm~(-1),F(000)=748,结构精修结果为:R_1=0.0287,wR_2=0.0640.簇阴离子[Fe_2S_2Br_4]~(2-)含有一个菱形Fe_2S_2单元,铁的配位几何构型明显偏离了理想的T_d对称性,导致整个阴离子的对称性降低为D_(2h).同时观察到它的Fe-Br键呈现反常加长倾向.     

含全螯合配位体的类立方烷型簇合物[(C_2H_5)_4N]_2{Fe_4S_4[S_2CN(C_2H_5)_2]_4}的合成、结构、性质及量化计算

在无氧无水和纯净氮气保护下,以FeCl_2,(NH_4)_2WS_4,NaS_2CN(C_2H_5)_2和(C_2H_5)_4NBr为原料,合成出了簇合物[(C_2H_5)_4N]_2{Fe_4S_4[S_2CN(C_2H_5)_2]_4}。其晶体属单斜晶系,Cc空间群,a=22.125(6),b=11.313(3),c=25.053(8);β=118.05(2),V=5534.2,Z=4。它具有类立方烷型核心Fe_4S_4,每个Fe原子上都有一个双硫螯合配位体S_2CN(C_2H_5)_2。Mssbauer谱、X光电子能谱及量子化学计算结果都表明,簇合物中含有两种数量相等而价态不同的Fe。提出了该簇合物生成反应的图解,报道了簇合物的红外光谱、紫外-可见光谱及氧化还原性质。     

簇离子Mo_3S_4M~（n＋）中M与Mo成键作用及电子光谱（M＝Fe、Ni，n＝4；M＝Cu，n＝5）

应用ＩＮＤＯ／Ｓ半经验量子化学方法，对簇合物离子Ｍｏ３Ｓ和Ｍｏ３Ｓ４Ｍｎ＋（Ｍ＝Ｆｅ、Ｎｉ，ｎ＝４；Ｍ＝Ｃｕ，ｎ＝５）分别进行分子轨道计算。根据计算得到的簇离子中的原子表观电荷和成键指标，说明Ｆｅ、Ｎｉ、Ｃｕ＋与Ｍｏ３Ｓ成键作用的相对强度依次是Ｆｅ－Ｍｏ＞Ｎｉ－Ｍｏ＞Ｃｕ＋－Ｍｏ。比较了用含组态作用的ＩＮＤＯ／Ｓ方法计算得到的电子跃迁能与实验得到的电子吸收光谱值，并讨论了吸收峰归属情况。对于Ｍ为Ｆｅ、Ｎｉ的簇离子Ｍｏ３Ｓ４Ｍ４＋，最低能量的电子跃迁吸收峰起源于异金属间电荷转移跃迁（ＭＭ’ＣＴ）；而Ｍｏ３Ｓ４Ｃｕ（５＋）簇离子观察到的吸收峰主要是Ｍｏ３Ｓ芯的局域内电荷转移跃迁。根据理论计算结果，由Ｃｕ＋离子到Ｍｏ３Ｓ的电荷转移跃迁谱线，大约在４６０００ｃｍ－１以上才能观察到吸收峰。从Ｍｏ３Ｓ４Ｆｅ４＋次低能量吸收峰的实验值１６６００ｃｍ－１和理论值１６５００ｃｍ－１与Ｍｏ３Ｓ的最低能量吸收峰的实验值１６６００ｃｍ－１和理论值１６９００ｃｍ－１比较，表明无论从理论上或实验上都能证实簇离子Ｍｏ３Ｓ４Ｆｅ４＋在能量为１６６００ｃｍ－１处的吸收峰是起因于Ｍｏ３Ｓ芯的局域内电荷转移跃迁。     

磁性Fe_3O_4-聚吡咯纳米微球的合成与表征

报道了具有核壳结构的Fe3O4 聚吡咯磁性纳米微球的合成方法和表征结果 .微球同时具有导电性和磁性能 .在优化的实验条件下 ,可得到饱和磁化强度为 2 3 4emu g ,矫顽力为 45 2Oe的磁性微球 .微球的导电性随着微球中Fe3O4含量的增加而下降 .微球的磁性能则随着Fe3O4含量的增加而增大 .Fe3O4磁流体的粒径和磁性聚吡咯微球的粒径均在纳米量级 .纳米Fe3O4粒子能够提高复合物的热性能 .实验表明 ,磁流体和聚吡咯之间存在着一定的相互作用 ,正是这种相互作用使磁性聚吡咯纳米微球的热稳定性提高 .     

丙炔醇聚合股对铁在酸性溶液中的缓蚀作用

应用电化学交流阻抗谱技术研究了Ｆｅ／Ｈ_２ＳＯ_４与Ｆｅ／Ｈ_２ＳＯ_４＋Ｈ_２Ｓ体系中丙炔醇（ＰＡ）聚合膜的形成及其缓蚀作用,同时利用ＳＥＭ、ＡＦＭ及ＥＤＸ对ＰＡ聚合不同时期铁表面腐蚀形貌进行观测与成分分析．结果表明,Ｆｅ／Ｈ_２ＳＯ_４与 Ｆｅ／Ｈ_２ＳＯ_４＋ Ｈ_２Ｓ体系中 ＰＡ可逐渐聚合成膜,从而有效抑制基体的腐蚀,使电极表面较为平整,微米尺度下呈现规则的块状结构;但Ｆｅ／Ｈ_２ＳＯ_４体系中宏观上ＰＡ并未形成连续的保护膜,导致电极表面局部发生腐蚀;而Ｆｅ／Ｈ_２ＳＯ_４＋Ｈ_２Ｓ体系中,Ｈ_２Ｓ、ＨＳ－在电极表面的吸附减缓了ＰＡ聚合成膜,但长时间腐蚀后,由于硫化物的生成覆盖在ＰＡ聚合膜上,使其具有长期缓蚀效能．     

Sequential oxidation of the cubane [4Fe--4S] cluster from [4Fe--4S](-) to [4Fe--4S](3+) in Fe(4)S(4)L(n)(-) complexes

Gaseous Fe(4)S(n)(-) (n = 4-6) clusters and synthetic analogue complexes, Fe(4)S(4)L(n)(-) (L = Cl, Br, I; n = 1-4), were produced by laser vaporization of a solid Fe/S target and electrospray from solution samples, respectively, and their electronic structures were probed by photoelectron spectroscopy. Low binding energy features derived from minority-spin Fe 3d electrons were clearly distinguished from S-derived bands. We showed that the electronic structure of the simplest Fe(4)S(4)(-) cubane cluster can be described by the two-layer spin-coupling model previously developed for the [4Fe] cubane analogues. The photoelectron data revealed that each extra S atom in Fe(4)S(5)(-) and Fe(4)S(6)(-) removes two minority-spin Fe 3d electrons from the [4Fe--4S] cubane core and each halogen ligand removes one Fe 3d electron from the cubane core in the Fe(4)S(4)L(n)(-) complexes, clearly revealing a behavior of sequential oxidation of the cubane over five formal oxidation states: [4Fe--4S](-) --> [4Fe--4S](0) --> [4Fe--4S](+) --> [4Fe-4S](2+) --> [4Fe-4S](3+). The current work shows the electron-storage capability of the [4Fe--4S] cubane, contributes to the understanding of its electronic structure, and further demonstrates the robustness of the cubane as a structural unit and electron-transfer center.     

磁场诱导下Fe3S4向FeS2转化速率的增加

以FeCl₃和CH₄N₂S为主要原料，在0.2～0.4 T的外加磁场强度下，温度为170 ℃的反应体系中研究了磁场对前驱物Fe₃S₄转化成FeS₂过程的影响。结果表明，Fe₃S₄到FeS₂的转化率是与磁场强度有关的。Fe₃S₄的硫化过程可能是通过溶解-再结晶机理。外加磁场的存在可以促进物质的传输过程，从而加速前驱物的溶解和再结晶过程，导致和没有外加磁场相比Fe₃S₄到FeS₂的转化率的增加。     

Fe(ClO_4)_3氧化合成聚乙撑二氧-三噻吩

分别以Fe(Cl O4)3、FeCl3、Fe2(SO4)3作为氧化剂,对3′,4′-乙撑二氧-2,2′∶5′,2″-三噻吩(TET)进行了化学氧化聚合,并研究了聚合条件对聚合物结构和电化学性能的影响。利用红外光谱、紫外光谱、X射线衍射对聚合物进行了表征,采用循环伏安、恒电流充放电等电化学方法研究了聚合物的电化学性能。结果表明:当TET与Fe(Cl O4)3的摩尔比为1∶4,反应温度为18℃,反应时间为12 h时,聚3′,4′-乙撑二氧-2,2′∶5′,2″-三噻吩(PTET)具有更好的共轭结构和电化学性能,导电率可达1.47 S/m,比电容可达133 F/g。     

A [4Fe-4S] cluster dimer bridged by bis(2,2':6',2'-terpyridine-4'-thiolato)iron(II)

The use of 2,2':6',2'-terpyridine-4'-thiol (tpySH) was explored as a bridging ligand for the formation of stable assemblies containing both [4Fe-4S] clusters and single metal ions. Reaction of tpySH (2 equiv) with (NH4)2Fe(SO4)(2).6H2O generated the homoleptic complex [Fe(tpySH)2](2+), which was isolated as its PF6(-) salt. The compound could be fully deprotonated to yield neutral [Fe(tpyS)2], and the absorption spectrum is highly dependent on the protonation state. Reaction of [Fe(tpySH)2](PF6)2 with the new 3:1 site-differentiated cluster (n-Bu4N)2[Fe4S4(TriS)(SEt)] yielded the first metal-bridged [4Fe-4S] cluster dimer, (n-Bu4N)2[{Fe4S4(TriS)(mu-Stpy)}2Fe]. Electrochemical studies indicate that the [4Fe-4S] clusters in the dimer act as independent redox units, while UV-vis spectroscopy provides strong evidence for a thioquinonoid electron distribution in the bridging tpyS(-) ligand. TpySH thus acts as a directional bridging ligand between [4Fe-4S] clusters and single metal ions, thereby opening the way to the synthesis of larger, more complex assemblies.     

Mass Spectrometric Identification of [4Fe–4S](NO)x Intermediates of Nitric Oxide Sensing by Regulatory Iron–Sulfur Cluster Proteins

Nitric oxide (NO) can function as both a cytotoxin and a signalling molecule. In both cases, reaction with iron–sulfur (Fe–S) cluster proteins plays an important role because Fe–S clusters are reactive towards NO and so are a primary site of general NO-induced damage (toxicity). This sensitivity to nitrosylation is harnessed in the growing group of regulatory proteins that function in sensing of NO via an Fe–S cluster. Although information about the products of cluster nitrosylation is now emerging, detection and identification of intermediates remains a major challenge, due to their transient nature and the difficulty in distinguishing spectroscopically similar iron-NO species. Here we report studies of the NO-sensing Fe–S cluster regulators NsrR and WhiD using non-denaturing mass spectrometry, in which non-covalent interactions between the protein and Fe/S/NO species are preserved. The data provide remarkable insight into the nitrosylation reactions, permitting identification, for the first time, of protein-bound mono-, di- and tetranitrosyl [4Fe–4S] cluster complexes ([4Fe–4S](NO), [4Fe–4S])(NO)₂ and [4Fe–4S](NO)₄) as intermediates along pathways to formation of product Roussin's red ester (RRE) and Roussin's black salt (RBS)-like species. The data allow the nitrosylation mechanisms of NsrR and WhiD to be elucidated and clearly distinguished.     

Density functional and reduction potential calculations of Fe4S4 clusters

Density functional theory geometry optimizations and reduction potential calculations are reported for all five known oxidation states of [Fe(4)S(4)(SCH(3))(4)](n)()(-) (n = 0, 1, 2, 3, 4) clusters that form the active sites of iron-sulfur proteins. The geometry-optimized structures tend to be slightly expanded relative to experiment, with the best comparison found in the [Fe(4)S(4)(SCH(3))(4)](2)(-) model cluster, having bond lengths 0.03 A longer on average than experimentally observed. Environmental effects are modeled with a continuum dielectric, allowing the solvent contribution to the reduction potential to be calculated. The calculated protein plus solvent effects on the reduction potentials of seven proteins (including high potential iron proteins, ferredoxins, the iron protein of nitrogenase, and the "X", "A", and "B" centers of photosystem I) are also examined. A good correlation between predicted and measured absolute reduction potentials for each oxidation state of the cluster is found, both for relative potentials within a given oxidation state and for the absolute potentials for all known couples. These calculations suggest that the number of amide dipole and hydrogen bonding interactions with the Fe(4)S(4) clusters play a key role in modulating the accessible redox couple. For the [Fe(4)S(4)](0) (all-ferrous) system, the experimentally observed S = 4 state is calculated to lie lowest in energy, and the predicted geometry and electronic properties for this state correlate well with the EXAFS and M?ssbauer data. Cluster geometries are also predicted for the [Fe(4)S(4)](4+) (all-ferric) system, and the calculated reduction potential for the [Fe(4)S(4)(SCH(3))(4)](1)(-)(/0) redox couple is in good agreement with that estimated for experimental model clusters containing alkylthiolate ligands.     

Sulfur K-edge XAS and DFT calculations on [Fe4S4]2+ clusters: effects of H-bonding and structural distortion on covalency and spin topology

Sulfur K-edge X-ray absorption spectroscopy of a hydrogen-bonded elongated [Fe4S4]2+ cube is reported. The data show that this synthetic cube is less covalent than a normal compressed cube with no hydrogen bonding. DFT calculations reveal that the observed difference in electronic structure has significant contributions from both the cluster distortion and from hydrogen bonding. The elongated and compressed Fe4S4 structures are found to have different spin topologies (i.e., orientation of the delocalized Fe2S2 subclusters which are antiferromagnetically coupled to each other). It is suggested that the H-bonding interaction with the counterion does not contribute to the cluster elongation. A magneto-structural correlation is developed for the Fe4S4 cube that is used to identify the redox-active Fe2S2 subclusters in active sites of HiPIP and ferredoxin proteins involving these clusters.