四甲基二硅桥连二（环己基环戊二烯基）四羰基二铁的合成、结构及热量排反应研究

1，2－二（环己基环戊二烯基）四甲基二硅烷与Fe(CO)_5在二甲苯中加热回流 生成二铁化合物(Me_2SiSiMe_2)[(c-C_6H_(11)-C_5H_3)Fe(CO)]_2(μ-CO)_2 （ 2）。通过柱层析分离到2的顺反两种异构体2c和2t，并分别进行热重排反应，发现 顺式底物2c重排生成反式重排产物[Me_2Si(c-C_6H_(11)C_5H_3)Fe(CO)_2]_2 （ 3t），而反式底物2t重排则生成顺式重排产物3c。这表明重排反应是立体专一性的 。通过X射线衍射分析测定了化合物2c和3t的晶体结构。     

四甲基二硅桥联茚基环戊二烯基四羰基二铁的合成、结构及热重排反应

ClMe₂SiSiMe₂Cl顺序与茚基锂和环戊二烯基锂作用,生成(1-C₉H₇)Me₂SiSiMe₂C₅H₅.后者进一步与五羰基铁反应,得到硅硅桥联茚基环戊二烯基化合物[η⁵,η⁵-(1-C₉H₆)Me₂SiSiMe₂C₅H₄]Fe₂(CO)₄ (2).化合物2在加热条件下发生重排反应,给出硅硅键和铁铁键复分解产物([-)Me₂Si(η⁵-1-C₉H₆)Fe(CO)₂SiMe2(η⁵-C₅H₄)Fe(CO)₂(]-) (3).利用X射线衍射法,测定了2和3的分子结构.     

碳锗双桥连二环戊二烯与羰基铁的反应

碳锗双桥连二环戊二烯(Me₂C)(Me₂Ge)(C₅H₄)₂(1)与五羰基铁在回流甲苯及二甲苯中的反应,得到正常的Fe-Fe键化合物(Me₂C)(Me₂Ge)[(η⁵-C₅H₃)Fe(CO)]₂(μ-CO)₂(3)和脱锗桥产物(Me₂C)[(η⁵-C₅H₄)Fe(CO)]₂(μ-CO)₂(4)以及一个结构新颖的化合物(Me₂C)[(η⁵-C₅H₃)[(Me₂Ge)Fe(CO)₂](η¹,η⁵-C₅H₃)[Fe(CO)₂](2).用X射线衍射分析測定了化合物3的晶体结构,并提出了可能的生成机理.     

1,2-双(四甲基环戊二烯基)四甲基二硅烷与六碳基钼的反应

1,2-双(四甲基环戊二烯基)四甲基二硅烷与正丁基锂作用生成(四甲基二硅撑)双(四甲基环戊二烯基负离子盐),后者随即与六碳基钼反应形成1,1'-(四甲基二硅撑)双(四甲基环戊二烯基铝负离子盐)-(Me₂SiSiMe₂)[Me₄CpMo(CO)₃-Li⁺]₂(I),I与冰醋酸作用,随即分别与CCl₄,NBS及I₂反应,生成相应的铝卤化合物(Me₂SiSiMe₂)[Me₄CpMo(CO)₃X]₂[X=Cl(1),Br(2),I(3)].I与CH₃I反应,在钼原子上发生烃基化,得到产物(Me₂SiSiMe₂)[Me₄CpMo(CO)₃Me]₂(4);I与单质I₂直接反应,生成脱硅桥产物Me₄Cp(CO)>₃I(5).经元素分析、IR及¹HNMR表征了化合物1-5的结构。     

硅桥连双(三甲硅基环戊二烯基)钛化合物的合成及脱硅基反应

硅桥连双(三甲硅基环戊二烯基)双锂盐与TiCl₄·2THF反应,生成相应的钛化合物[E(C₅H₃SiMe₃)₂]TiCl₂[E=Me₂SiSiMe₂(3),Me₂SiOSiMe₂(5)],同时还分离到了脱一个三甲硅基的产物[E(C₅H₄)(C₅H₃SiMe₃)]TiCl₂[E=Me₂SiSiMe₂(4),Me₂SiOSiMe₂(6)].其中四甲基二硅氧桥连配体更容易发生这种脱硅基反应.通过元素分析、MS和¹HNMR谱表征了化合物3-6的分子结构.     

基于偶氮桥连的新型双铁羰基配合物:Fe2(N2C5H10)(CO)6-x (PR3)x的合成及衍生

具有五元环结构的偶氮化合物4,4-二甲基-4,5-二氢-3H-吡咯（N₂C₅H₁₀）,与Fe₃（CO）₁₂在甲苯中加热回流反应,生成双铁六羰基配合物Fe₂（N₂C₅H₁₀）（CO）₆（1）.反应中N=N双键被还原,配体以（N₂C₅H₁₀）^2-的形式与Fe^IFe^I配位,形成具有蝶形结构的34e^-化合物.研究了在脱羰基试剂Me₃NO存在条件下,1和单齿膦配体PR₃反应生成Fe₂（N₂C₅H₁₀）-（CO）₅（PR₃）（PR₃=PPh₃,2a;PCy₃,2b）单取代配合物.光照条件下,化合物1中的CO配体还可以被双齿膦配体dppe[dppe=1,2-C₂H₄（PPh₂）₂]和dppbz[dppbz=1,2-C₆H₄（PPh₂）₂]取代,生成产物的类型和膦配体的夹角相关.与夹角较大的dppe反应,生成桥连产物Fe₂（N₂C₅H₁₀）（CO）₄（μ-dppe）（3a）;而与刚性较大的dppbz反应时,Fe₂（NR）₂的蝶形结构打开呈四元环;其中一个Fe上的CO被取代,dppbz与该Fe中心螯合,生成具有桥连CO的化合物Fe₂（N₂C₅H₁₀）（μ-CO）（CO）₄（κ²-dppbz）（3b）.合成具有Fe^I-CO-Fe^I结构的羰基化合物,一直是模拟[FeFe]氢化酶活性中心还原态结构Fe₂（SR）₂（μ-CO）-（CO）_5-xL_x的重要挑战.该类Fe₂（NR）₂（CO）_6-x（PR₃）_x化合物的合成,能为探索模拟[FeFe]氢化酶活性中心结构提供新的途径和思路.以上化合物均通过核磁[³¹P（¹H）NMR]、红外光谱（IR）、元素分析及X射线单晶结构衍射等表征.     

三(三甲基硅)环戊二烯与六羰基钼的反应

三(三甲基硅)环戊二烯与六羰基钼在二甲苯中回流8h,反应停留在生成中间物η⁵-[(Me₃Si)_NC₅H_5-n]Mo(CO)₃H(n=2,3)(I)的阶段.不经分离,I随即分别与CCl₄·NBS及MeI反应,生成其相应的钼卤化物η-⁵[(Me₃Si)_NC₅H_5-n]Mo(CO)₃X[n=3,X=Cl(1),Br(2),I(3);n=2,X=Cl(4),Br(5),I(6)].4-6是由于茂环上脱掉1个Me₃Si基.经元素分析和IR及¹H NMR谱表征了化合物1-6的结构,并用X射线衍射测定了1的晶体结构.     

二硫代乙酰丙酮和某些金属离子络合反应的研究

报导CH₃COCH₂COCH₃/H-2S/C₂H₅OH-HCl体系和十六种金属离子以及Fe(CO)₅的反应,用X射线衍射法测定了九种反应产物的分子和晶体结构.本文结果总结出了该反应的规律性.研究表明,在该反应条件下,钼是唯一能够形成原子簇化合物的元素.     

新型双四面体过渡金属簇合物的合成与表征

利用Co₂(CO)₈与[Cl₃CC(O)OCH₂]₂的反应合成了以C(O)OCH₂CH₂OC(O)桥联两个Co₃C四面体骨架为特征的新型双四面体簇合物[(CO)₉Co₃(μ₃-C)C(O)OCH₂]₂(1);1与不同物质的量比的Na[M(CO)₃C₅H₄R](M=Mo,W;R=H,C(O)Me)反应,得到一步交换的产物(CO)₉Co₃(μ₃-C)C(O)OCH₂CH₂OC(O)(μ₃-C)Co₂M(CO)₈(C₅H₄R)[M=Mo,R=H(2);M=Mo,R=C(O)Me(3);M=W,R=H(4);M=W,R=C(O)Me(5)]或两步交换的产物[(C₅H₄R)(CO)₈Co₂M(μ₃-C)C(O)OCH₂]₂[M=Mo,R=H(6);M=Mo,R=C(O)Me(7);M=W,R=H(8);M=W,R=C(O)Me(9)].5或9分别与Na[Mo(CO)₃C₅H₅]以12的物质的量比反应得到含一个手性四面体骨架(CoMoWC)的(C₅H₅)(CO)₈Co₂Mo(μ₃-C)C(O)OCH₂CH₂O·C(O)(μ₃-C)CoMoW(CO)₇(C₅H₄C(O)Me)(C₅H₅)(10)或含两个手性四面体骨架(CoMoWC)的[(C₅H₅)(C₅H₄C(O)Me)(CO)₇CoMoW(μ₃-C)C(O)OCH₂]₂(11);对化合物1_11进行了CH元素分析、IR和¹HNMR等表征.结果表明,在金属交换反应中处于不同簇环境下的Co(CO)₃基团反应活性不同.对化合物1进行了晶体X射线衍射分析.化合物1的晶体属单斜晶系,P2₁/n(#14)空间群,晶胞参数a=0.933 0(2)nm,b=1.519 7(4)nm,c=1.178 3(4)nm,=91.16(2)°,Z=2,F(000)=972.分子结构呈中心对称.     

含钼(钨)锡键的四元金属有机杂环化合物的合成与反应研究

通过三苯基锡基-双(3,5-二甲基吡唑)甲烷与羰基钼的反应合成了钼锡键合的四元金属杂环化合物CH(3,5- Me₂Pz)₂Mo(CO)₃SnPh₃ (Pz＝1-吡唑基). 当用叔丁基异腈处理该化合物及其钨类似物时, 伴随着有机锡结构单元的丢失, 金属钼(钨)上发生还原消除并分解得到化合物CH₂(3,5-Me₂Pz)₂M(CO)₃(CNBu-t) (M为Mo或W). 另外, 该化合物与三苯基膦或亚磷酸甲酯及异丙酯反应时, 只发生羰基取代反应得到化合物CH(3,5-Me₂Pz)₂Mo(CO)₂(PR₃)SnPh₃ (R为苯基、甲氧基及异丙氧基). 而用亚磷酸苯酯与之反应, 除得到羰基取代产物外, 还伴随着P-O/C键的交换, 得到金属钼上还原消除的产物(PhO)₂PCH(3,5-Me₂Pz)₂Mo(CO)₃.     

Synthesis of tetramethyldisilane-bridged bis(1-indenyl) tetracarbonyl di-iron: A novel thermal rearrangement reaction between the Si-Si and Fe-Fe bonds

The title complex (Me₂SiSiMe₂)(η⁵-l-indenyl)Fe(CO)]₂(μ-CO)₂ (1) was prepared by the reaction of 1,2-bis(1-indenyl)tetramethyl-disilane and Fe(CO)₅ in refluxing heptane. Its thermal rearrangement product [Me₂Si(η⁵-1-indenyl)Fe(CO)₂]₂ (2) was also obtained from the reaction. 1 in refluxing xylene can be readily converted into 2. The crystal structures of the cis isomer 1c and the trans isomer 2t were determined by X-ray diffraction.     

Organopolysilane oligomers bearing transition-metal moieties: Synthesis, reactivities and molecular structure of [η-Me3SiMe2SiC5H4(CO)Fe(CO)2Fe(CO)-η-C5H4SiMe2SiME3]

Reaction of Me₃SiMe₂SiC₅H₅ (4), prepared from Me₃SiMe₂SiCl and C₅H₅Na, with Fe(CO)₅ in refluxing xylene afforded the title compound (3). The silicon-silicon bond in 3 is exceptionally stable in refluxing xylene and also in succeeding reactions to prepare a series of its derivatives. Thus, 3 reacted with I₂ in either chloroform or benzene, giving [η⁵-Me₃SiMe₂SiC₅H₄Fe(CO)₂I] (6). Compound 3 was reduced by sodium amalgam and reacted subsequently with CH₃I, PhCH₂Cl, CH₃COCl, PhCOCl, Cy₃SnCl (Cy = cyclohexyl) and Ph₃SnCl, producing [η⁵-Me₃SiMe₂SiC₅H₄Fe(CO)₂R][7 : R = CH₃ (a), PhCH₂ (b), CH₃CO (c), PhCO (d), Cy₃Sn (e) and Ph₃Sn (f), respectively]. The molecular structure of 3 has been determined by X-ray diffraction crystallography. It was found that 3 has a trans-configuration with a symmetrical centre located at the middle of the Fe---Fe bond. It is abnormal that the conformation of the disilane part around the Si---Si bond is almost eclipsed rather than staggered.     

Thirty years of organometallic aryldiazenido arylazo derivatives

The aryldiazenido ligands provide the fourth member of the isoelectronic series CO, NO⁺, RNC, RN₂⁺ of ligands for transition metal complexes. The first aryldiazenido metal complex was reported in 1964 when p-CH₃OC₆H₄N₂Mo(CO)₂C₅H₅ was prepared by the reaction of NaMo(CO)₃C₅H₅ with p-CH₃OC₆H₄N₂⁺BF₄⁻. This review surveys the development of organometallic aryldiazenido chemistry since that time. Such organometallic aryldiazenido derivatives, including RN₂M(CO)₂C₅H₅, RN₂M(CO)₂(Pz₃BH) (M = Cr, Mo, W), [(η⁶-Me₆C₆)Cr(CO)₂N₂Ar]⁺, [(MeC₁₅H₄)M′(CO)₂N₂Ar]⁺ M′ = Mn, Re), [trans-PhN₂Fe(CO)₂(PPh₃)₂]⁺, and PhN₂M′(CO)₂(PPh₃)₂(PPh₃)₂ can be obtained by reactions of arenediazonium salts with suitably chosen transition metal nucleophiles. Analogous methods cannot be used to prepare alkyldiazenido transition metal complexes because of the instability of alkyldiazonium salts. However, the alkyldiazenido derivatives RCH₂N₂M(CO)₂C₅H₅ (R = H or Me₃Si) can be obtained from HM(CO)₃C₅H₅ and the corresponding diazoalkanes. Important aspects of the chemical reactivity of RN₂M(CO)₂Q derivatives (Q = C₅H₅, Pz₃BH) include CO substitution reactions, coordination of the second nitrogen in the RN₂ ligand to give heterobimetallic complexes such as C₅H₅Mo(CO)₂(μ-NNC₆H₄Me)(CO)₂C₅H₅, oxidative addition rections with X₂ X = Cl, Br, I), SnX₄, RSSR, and CINO, and reactions with further RN₂⁺ to give bis(aryldiazenido) derivatives (RN₂)₂MQL⁺ (L = CO, X⁻, etc.). Dearylation of an aryldiazenido ligand to a dinitrogen ligand can be effected by reaction of [(MeC₅H₄)M′(CO)₂N₂Ar]⁺ with certain nucleophiles to give (MeC₅H₄)M′(CO)₂N₂.     

Group 4 metallacarboranes of constrained geometries derived from B(cage)- and C(cage)-silylamido-substituted carborane ligands: a synthetic and structural investigation

The reactions of RNHSi(Me)₂Cl (1, R=t-Bu; 2, R=2,6-(Me₂CH)₂C₆H₃) with the carborane ligands, nido-1-Na(C₄H₈O)-2,3-(SiMe₃)₂-2,3-C₂B₄H₅ (3) and Li[closo-1-R′-1,2-C₂B₁₀H₁₀] (4), produced two kinds of neutral ligand precursors, nido-5-[Si(Me)₂N(H)R]-2,3-(SiMe₃)₂-2,3-C₂B₄H₅, (5, R=t-Bu) and closo-1-R′-2-[Si(Me)₂N(H)R]-1,2-C₂B₁₀H₁₀ (6, R=t-Bu, R′=Ph; 7, R=2,6-(Me₂CH)₂C₆H₃, R′=H), in 85, 92, and 95% yields, respectively. Treatment of closo-2-[Si(Me)₂NH(2,6-(Me₂CH)₂C₆H₃)]-1,2-C₂B₁₀H₁₁ (7) with three equivalents of freshly cut sodium metal in the presence of naphthalene produced the corresponding cage-opened sodium salt of the “carbons apart” carborane trianion, [nido-3-{Si(Me)₂N(2,6-(Me₂CH)₂C₆H₃)}-1,3-C₂B₁₀H₁₁]³⁻ (8) in almost quantitative yield. The reaction of the trianion, 8, with anhydrous MCl₄ (M=Ti and Zr) in 1:1 molar ratio in dry tetrahydrofuran (THF) at −78 °C, resulted in the formation of the corresponding half-sandwich neutral d⁰-metallacarborane, closo-1-M[(Cl)(THF)_n]-2-[1′-η¹σ-N(2,6-(Me₂CH)₂C₆H₃)(Me)₂Si]-2,4-η⁶-C₂B₁₀H₁₁ (M=Ti (9), n=0; M=Zr (10), n=1) in 47 and 36% yields, respectively. All compounds were characterized by elemental analysis, ¹H-, ¹¹B-, and ¹³C-NMR spectra and IR spectra. The carborane ligand, 7, was also characterized by single crystal X-ray diffraction. Compound 7 crystallizes in the monoclinic space group P2₁/c with a=8.2357(19) Å, b=28.686(7) Å, c=9.921(2) Å; β=93.482(4)°; V=2339.5(9) ų, and Z=4. The final refinements of 7 converged at R=0.0736; wR=0.1494; GOF=1.372 for observed reflections.     

双(2,4-二甲基戊二烯基)氯化钆的合成及晶体结构

合成双(2,4-二甲基戊二烯基)氯化钆{[2,4-(CH₃)₂C₅H₅]₂GD_cl}₂,并测定了晶体结构.晶体为单斜晶系,P2₁/n空间群.晶胞参数a=0.89141(18)nm,b=1.4486(3)nm,c=1.15925(15)nm,β=92.996(18)°,V=1.4949(4)nm³,Z=3.     

Novel cyclopentadienyl silanes and disilanes: synthesis, structure and gas-phase pyrolysis

The new chloro(cyclopentadienyl)silanes Cp′SiH_yCl_3−y (Cp′=Me₄EtC₅, y=1: 1; Cp′=Me₄C₅H, y=1: 2; y=0: 3; Cp′=Me₃C₅H₂, y=1: 4 and pentachloro(cyclopentadienyl)disilanes Cp′Si₂Cl₅ (Cp′=Me₅C₅ 5, Me₄EtC₅ 6, Me₄C₅H 7, Me₃C₅H₂ 8, Me₃SiC₅H₄ 9) are synthesized in good yields via metathesis reactions. Treatment of 1–9 with LiAlH₄ leads under Cl–H exchange to the hydridosilyl compounds Cp′SiH₃ (Cp′=Me₄EtC₅ 10, Me₄C₅H 11, Me₃C₅H₂ 12) and to the hydridodisilanyl compounds Cp′Si₂H₅ (Cp′=Me₅C₅ 13, Me₄EtC₅ 14, Me₄C₅H 15, Me₃C₅H₂ 16, Me₃SiC₅H₄ 17). Complexes 1–17 are characterized by ¹H, ¹³C, and ²⁹Si-NMR spectroscopy, IR spectroscopy, mass spectrometry and CH-analysis. The structures of 6, 7 and 9 are determined by single-crystal X-ray diffraction analysis. Pyrolysis studies of the cyclopentadienylsilanes 10–12 and disilanes 13–17 show their suitability as precursors in the MOCVD process.     

Synthesis and structural characterization of sulfonates, phosphinates and carboxylates of organometallic Group 4 metal fluorides

Reaction of [Cp^*TiF₃] (Cp^* = (ν⁵-C₅Me₅)) with Me₃SiOSO₂- p-C₆H₄CH₃, Me₃SiOPOPh₂ and 1,2-(Me₃SiOCO)₂C₆H₄ yields the dinuclear complexes [{Cp^*TiF(μ-F)(μ-OSO₂-p-C₆H₄CH₄)}₂] (1), [{Cp^*TiF(μ-F)(μ-OPOPh₂)}₂] (2) and [{Cp^*TiF(μ-F)(μ-OCO-o-C₆H₄CO₂SiMe₃)}₂] (3). The molecular structures of 1 and 2 have been determined by single-crystal X-ray analysis. In complexes 1-3, the two titanium atoms are connected by bridging fluorine atoms as well as bridging sulfonate, phosphinate and carboxylate groups respectively. Each titanium atom is also bonded to a terminal fluorine atom. Reaction of [Cp₂^*ZrF₂] with 1,2-(Me₃SiOCO)₂C₆H₄ leads to the mononuclear pentacoordinate 18-electron species [Cp₂^*ZrF(μ-OCO-o-C₆H₄CO₂SiMe₃)] (4) and its structure was determined by X-ray crystallographic methods.