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1.
Reaction of [Pt 2(η 5-C 5Me 5) 2(η-Br) 3] 3+(Br −) 3 with C 5R 5H (R = H,Me) in the presence of AgBF 4 gives the first platinocenium dications, [Pt(η 5-C 5Me 5)(η 5-C 5R 5)] 2+(BF 4− ) 2. On electrochemical reduction, [pt(η 5-C 5Me 5) 2] 2+ yields [Pt(η 4-C 5Me 5H)(η 2-C 5Me 5)]+ BF 4−. kw]Cyclopentadienyl; Metallocenes; Platinum; Electrochemistry 相似文献
2.
13C and 31P{ 1H} NMR data at low temperature prompted us to characterize cis-[Rh(CO) 2(PR 3)Cl] (3) (3a, PR 3 = PPh 3; 3b, PR 3 = PMe 2Ph), as surprisingly stable products of the reaction between [{Rh(CO) 2(μ-Cl)} 2] (1) and tertiary phosphines in toluene (P : Rh = 1). Every attempt to isolate solid 3a led to the cis- and trans- halide-bridged dimers [{Rh(CO) 2(μ-Cl)} 2] (5a) and 6a which are formed from 3a by slow decarbonylation, a process which is greatly accelerated by the evaporation of the solvent under vacuum. The analogous reaction of 1 with dimethylphenylphosphine follows a similar pathway; in this case, however, low temperature NMR spectra allowed us to characterize the pentacoordinated dinuclear species [{Rh(CO)2(μ-Cl)}2] (2b) as the unstable intermediate of the bridge-splitting process. The reaction of 3 with a second equivalent of phosphine (P : Rh = 2) leads, at room temperature, to the well known product trans-[Rh(CO)(PR3)2Cl] (8) accompanied by evolution of CO; however our data show that when the reaction is performed at 200 K, decarbonylation is prevented and spectroscopic evidence of trigonal bipyramidal pentacoordinate [Rh(CO)2(PR3)2Cl] (7), stable only at low temperature, can be obtained. 相似文献
3.
The synthesis of the new (η 2-dppe)(η 5-C 5Me 5)Fe---CC---1,3-(C 6H 4X) ( m-2a/2b; X=F/Br) and (η 2-dppe)(η 5-C 5Me 5)Fe---CC---1,4-(C 6H 4I) (2c) complexes, as well as the solid-state structure of the known (η 2-dppe)(η 5-C 5Me 5)Fe---CC---1,4-(C 6H 4F) (2a) complex are described. The catalytic coupling reactions of the bromo complexes with various alkynes were next investigated. Starting from the known (η 2-dppe)(η 5-C 5Me 5)Fe---CC---1,4-(C 6H 4Br) complex (2b), the synthesis of the (η 2-dppe)(η 5-C 5Me 5)Fe---CC---1,4-(C 6H 4)---CC---H complex (6d) and of the corresponding silyl-protected precursors (η 2-dppe)(η 5-C 5Me 5)Fe---CC---1,4-(C 6H 4)CC---SiR 3 (6b/6c; R= iPr/Me) are reported. By use of lithium---bromine exchange reactions on 2b, the silyl- (7a; E=Si; R=Me) and tin- (7b–7d; E=Sn; R=Me, Bu, Ph) substituted analogues (η 2-dppe)(η 5-C 5Me 5)Fe---CC---1,4-(C 6H 4)ER 3 are also isolated. The spectroscopic and electrochemical characterisations of all these new Fe(II)/Fe(III) redox-active building blocks are presented and the electronic substituent parameters for the “(η 2-dppe)(η 5-C 5Me 5)Fe---CC” group are determined by means of 19F-NMR. 相似文献
4.
使用桥连配体锂盐与MCl 4络合, 合成了4个不同结构的双核茂金属化合物[ μ, μ-(CH 2) 3]{[C(H)·( η5-C 5H 4)( η5-C 13H 8)](MCl 2)} 2[M=Zr or Ti](4, 5)和[ μ, μ-(CH 2) 3]{[C(H)( η5-C 5H 4)( η5-C 9H 6)]·(MCl 2)} 2[M=Zr or Ti](6, 7), 配体和化合物都经过核磁氢谱( 1H NMR)、 碳谱( 13C NMR)、 红外光谱(IR)及元素分析等表征, 确认了化学结构. 以甲基铝氧烷(MAO)为助催化剂, 化合物4~7为催化剂催化丙烯聚合, 考察了聚合温度、 乙烯压力、 铝钛或铝锆比对催化剂活性及聚合物分子量的影响. 结果表明, 多亚甲基桥连双核茂金属是高活性乙烯和丙烯聚合催化剂, 乙烯聚合活性最高达到7.5× 10 6 g PE/(mol Zr·h)(化合物6), 丙烯聚合活性达 10 × 10 5 g sPP/(mol Zr·h)(化合物4). 所得间规聚丙烯(sPP)的间规度指数(SI, r) 达到90%. 在同样条件下, 双核化合物的催化活性、 聚合物分子量 Mw(> 100000)以及分子量分布(MWD>2.5)均比相应的单核化合物高( Mw<70000, MWD≤2), 表明该体系中存在较强的核效应. 相似文献
5.
An improved synthetic method has been found for the preparation of the pentamethylcyclopentadienyl rhenium dicarbonyldihalide complexes. From the reaction of (η 5-C 5Me 5)Re(CO) 3 with Br 2 or I 2 in THF-H 2O a mixture of cis and trans isomers of (η 5-C 5Me 5)Re(CO) 2X 2 X = Br and I is formed. On the other hand, the reaction of [(η 5-C 5Me 5)Re(CO) 3C1][SbC1 6] in water gives the cis-(η 5-C 5Me 5)Re(CO) 2C1 2 complex. The solid IR spectra of the dicarbonyldihalide complexes are recorded and an assignment of the normal modes in terms of local symmetry is suggested by comparison with those observed in analogous molecules. A normal coordinate analysis performed using a modified general valence force field and considering simplified models, confirms most of the experimental assignments. The set of valence force constants reflects the structure of the isomers under study. 相似文献
6.
The structures of the versatile starting compounds for organoiron complexes, the cationic aqua complex [(η 5-C 5Me 4Et)Fe(CO) 2(OH 2)]BF 4 (1b) and the halide complexes (η 5-C 5Me 5)Fe(CO) 2-I (2a), (η 5-C 5Me 4Et)Fe(CO) 2-I (2b) and (η 5-C 5Me 4Et)Fe(CO) 2-Cl (3b), are characterized by X-ray crystallography. Complex 1b [Fe---O: 2.022(8) Å and 2.043(9) Å, two independent molecules] is the first structurally characterized example of organoiron aqua complexes. Details of the synthetic procedures for the above complexes and the labile cationic THF complexes [η 5-C 5R 5)Fe(CO) 2(THF)]BF 4 (4) are disclosed, and the dissociation equilibrium of 4 is confirmed by means of variable temperature 1H-NMR as well as saturation transfer experiment. 相似文献
7.
We describe the redox behaviour in non-aqueous solvents of some cyclopentadienyl(oxo)titanium derivatives. The derivative [Ti 4{η 5-C 5H 4(SiMe 3)} 4(μ-O) 6] shows an electrochemically and chemically reversible le reduction process, followed by a multi-electron, chemically complicated reduction at a fairly cathodic potential. On the basis of the overall electrochemical features and the comparison with the redox behaviour of the quasi-planar compound [[Ti{η 5-C 5H 4(SiMe 3)}Cl(μ-O)] 4] we propose an EECCEE mechanism for the first derivative, where the second electron-transfer induces a cascade of chemical reactions giving rise to irreversible cluster breakdown. The electrochemically induced fragmentation can be viewed as a retrosynthetic pathway. The heterometallic derivative [{Ti(η 5-C 5H 4Me) 2(μ 2-MoO 4) 2} 2] shows two consecutive reduction processes; the first is chemically reversible, and the second quasi-reversible. The molybdate bridges apparently increase the stability of the electrogenerated anions. However none of these poly-oxo clusters can be considered as good models of electron ‘sinks’. 相似文献
8.
The complex [MoW(μ-CC 6H 4Me-4)(CO) 2(η 7-C 7H 7)(η 5-C 2B 9H 10Me)] reacts with diazomethane in Et 2O containing EtOH to afford the dimetal compound [MoW(OEt)(μ-CH 2){μ-C(C 6H 4Me-4)C(Me)O}(η 7-C 7H 7)(η 5-C 2B 9H 10Me)]. The structure of this product was established by X-ray diffraction. The Mo---W bond [2.778(4) Å] is bridged by a CH 2 group [μ-C---Mo 2.14(3), μ-C---W 2.02(3) Å] and by a C(C 6H 4Me-4)C(Me)O fragment [Mo---O 2.11(3), W---O 2.18(2), Mo---C(C 6H 4Me-4) 2.41(3), W---C(C 6H 4Me-4) 2.09(3), Mo---C(Me) 2.26(3) Å]. The molybdenum atom is η 7-coordinated by the C 7H 7 ring and the tungsten atom is η 5-coordinated by the open pentagonal face of the nido-icosahedral C 2B 9H 10Me cage. The tungsten atom also carries a terminally bound OEt group [W---O 1.88(3) Å]. The 1H and 13C-{ 1H} NMR data for the dimetal compound are reported and discussed. 相似文献
9.
In order to understand the nature of the putative cationic 12-electron species [M(η 5:η 1-C 5R 4SiMe 2NR′)R″] + of titanium catalysts supported by a linked amido-cyclopentadienyl ligand, several derivatives with different cyclopentadienyl C 5R 4 and amido substituents R′ were studied systematically. The use of tridentate variants (C 5R 4SiMe 2NCH 2CH 2X) 2− (C 5R 4=C 5Me 4, C 5H 4, C 5H 3tBu; X=OMe, SMe, NMe 2) allowed the NMR spectroscopic observation of the titanium benzyl cations [Ti(η 5:η 1-C 5Me 4SiMe 2NCH 2CH 2X)(CH 2Ph)] +. Isoelectronic neutral rare earth metal complexes [Ln(η 5:η 1-C 5R 4SiMe 2NR′)R″] can be expected to be active for polymerization. To arrive at neutral 12-electron hydride and alkyl species of the rare earth metals, we employed a lanthanide tris(alkyl) complex [Ln(CH 2SiMe 3) 3(THF) 2] (Ln=Y, Lu, Yb, Er, Tb), which allows the facile synthesis of the linked amido-cyclopentadienyl complex [Ln(η 5:η 1-C 5Me 4SiMe 2NCMe 3)(CH 2SiMe 3)(THF)]. Hydrogenolysis of the linked amido-cyclopentadienyl alkyl complex leads to the dimeric hydrido complex [Ln(η 5:η 1-C 5Me 4SiMe 2NCMe 3)(THF)(μ-H)] 2. These complexes are single-site, single-component catalysts for the polymerization of ethylene and a variety of polar monomers such as acrylates and acrylonitrile. Nonpolar monomers such as -olefins and styrene, in contrast, give isolable mono-insertion products which allow detailed studies of the initiation process. 相似文献
10.
Reaction of cis-[Ptph 2(SMe 2) 2] with Me 2PCH 2PMe 2 (dmpm) gave cis-[PtPh 2(dmpm-P) 2] (1) or cis,cis-[Pt 2Ph 4(μ-dmpm) 2] (2) and reaction of 1 with [Pt 2Me 4(μ-SMe 2) 2] gave cis,cis-[Ph 2Pt(μ-dmpm) 2PtMe 2] (3). Reaction of 1 with trans-[PtClR(SMe 2) 2] gave cis, trans-[Ph 2Pt(μ-dmpm) 2PtClR], R = Me (5) or Ph (6), and in polar solvents, these isomerized to give [Ph 2Pt(μ-dmpm) 2PtR] +Cl −. When R = Me, further isomerization via the phenyl group transfer gave [PhMePt(μ-dmpm) 2PtPh] +Cl −. Oxidative addition of methyl iodide occurred reversibly at the cis-[PtMe 2P 2 unit of 3 to give cis, fac-[Ph 2Pt(μ-dmpm) 2PtIMe 3] but complex 2 failed to react with MeI. A comparison with similar known complexes of Ph 2PCH 2PPh 2 (dppm) is made and differences are attributed primarily to the lower steric hindrance of dmpm. 相似文献
11.
Reaction of [Cp *TiF 3] (Cp * = (ν 5-C 5Me 5)) with Me 3SiOSO 2- p-C 6H 4CH 3, Me 3SiOPOPh 2 and 1,2-(Me 3SiOCO) 2C 6H 4 yields the dinuclear complexes [{Cp *TiF(μ-F)(μ-OSO 2- p-C 6H 4CH 4)} 2] (1), [{Cp *TiF(μ-F)(μ-OPOPh 2)} 2] (2) and [{Cp *TiF(μ-F)(μ-OCO- o-C 6H 4CO 2SiMe 3)} 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 [Cp 2*ZrF 2] with 1,2-(Me 3SiOCO) 2C 6H 4 leads to the mononuclear pentacoordinate 18-electron species [Cp 2*ZrF(μ-OCO- o-C 6H 4CO 2SiMe 3)] (4) and its structure was determined by X-ray crystallographic methods. 相似文献
12.
The dimethylphosphino substituted cyclopentadienyl precursor compounds [M(C 5Me 4CH 2PMe 2)], where M=Li + (1), Na + (2), or K + (3), and [Li(C 5H 4CR′ 2PMe 2)], where R′ 2=Me 2 (4), or (CH 2) 5 (5), [HC 5Me 4CH 2PMe 2H]X, where X −=Cl − (6) or PF 6− (7) and [HC 5Me 4CH 2PMe 2] (8), are described. They have been used to prepare new metallocene compounds, of which representative examples are [Fe(η-C 5R 4CR′ 2PMe 2) 2], where R=Me, R′=H (9); R=H and R′ 2=Me 2 (10), or (CH 2) 5 (11), [Fe(η-C 5H 4CMe 2PMe 3) 2]I 2 (12), [Fe{η-C 5Me 4CH 2P(O)Me 2} 2] (13), [Zr(η-C 5R 4CR′ 2PMe 2) 2Cl 2], where R=H, R′=Me (14), or R=Me, R′=H (15), [Hf(η-C 5H 4CMe 2PMe 2) 2]Cl 2] (16), [Zr(η-C 5H 4CMe 2PMe 2) 2Me 2] (17), {[Zr(η-C 5Me 4CH 2PMe 2) 2]Cl}{(C 6F 5) 3BClB(C 6F 5) 3} (18), [Zr{(η-C 5Me 4CH 2PMe 2) 2Cl 2}PtI 2] (19), [Mn(η-C 5Me 4CH 2PMe 2) 2] (20), [Mn{(η-C 5Me 4CH 2PMe 2B(C 6F 5) 3} 2] (21), [Pb(η-C 5H 4CMe 2PMe 2) 2] (23), [Sn(η-C 5H 4CMe 2PMe 2) 2] (24), [Pb{η-C 5H 4CMe 2PMe 2B(C 6F 5) 3} 2] (25), [Pb(η-C 5H 4CMe 2PMe 2) 2PtI 2] (26), [Rh(η-C 5Me 4CH 2PMe 2)(C 2H 4)] 29, [M(η,κ P-C 5Me 4CH 2PMe 2)I 2], where M=Rh (30), or Ir, (31). 相似文献
13.
Reactions of [(η 6-arene)RuCl 2] 2 (1) (η 6-arene= p-cymene (1a), 1,3,5-Me 3C 6H 3 (1b), 1,2,3-Me 3C 6H 3 (1c) 1,2,3,4-Me 4C 6H 2(1d), 1,2,3,5-Me 4C 6H 2 (1e) and C 6Me 6 (1f)) or [Cp*MCl 2] 2 (M=Rh (2), Ir (3); Cp*=C 5Me 5) with 4-isocyanoazobenzene (RNC) and 4,4′-diisocyanoazobenzene (CN–R–NC) gave mononuclear and dinuclear complexes, [(η 6-arene)Ru(CNC 6H 4N=NC 6H 5)Cl 2] (4a–f), [Cp*M(CNC 6H 4N=NC 6H 5)Cl 2] (5: M=Rh; 6: M=Ir) , [{(η 6-arene)RuCl 2} 2{μ-CNC 6H 4N=NC 6H 4NC}] (8a–f) and [(Cp*MCl 2) 2(μ-CNC 6H 4N=NC 6H 4NC)}] (9: M=Rh; 10: M=Ir) , respectively. It was confirmed by X-ray analyses of 4a and 5 that these complexes have trans-forms for the ---N=N--- moieties. Reaction of [Cp*Rh(dppf)(MeCN)](PF 6) 2 (dppf=1,1′-bis (diphenylphosphino)ferrocene) with 4-isocyanoazobenzene gave [Cp*Rh(dppf)(CNC 6H 4N=NC 6H 5)](PF 6) 2 (7), confirmed by X-ray analysis. Complex 8b reacted with Ag(CF 3SO 3), giving a rectangular tetranuclear complex 11b, [{(η 6-1,3,5-Me 3C 6H 3)Ru(μ-Cl} 4(μ-CNC 6H 4N=NC 6H 4NC) 2](CF 3SO 3) 4 bridged by four Cl atoms and two μ-diisocyanoazobenzene ligands. Photochemical reactions of the ruthenium complexes (4 and 8) led to the decomposition of the complexes, whereas those of 5, 7, 9 and 10 underwent a trans-to- cis isomerization. In the electrochemical reactions the reductive waves about −1.50 V for 4 and −1.44 V for 8 are due to the reduction of azo group, [---N=N---]→[---N=N---] 2−. The irreversible oxidative waves at ca. 0.87 V for the 4 and at ca. 0.85 V for 8 came from the oxidation of Ru(II)→Ru(III). 相似文献
14.
The reactions of the half-sandwich molybdenum(III) complexes CpMo(η 4-C 4H 4R 2)(CH 3) 2, where Cp=η 5-C 5H 5 and R=H or CH 3, with equimolar amounts of B(C 6F 5) 3 have been investigated in toluene. EPR monitoring shows the formation of an addition product which does not readily react with Lewis bases such as ethylene, pyridine, or PMe 3. The analysis of the EPR properties and the X-ray structure of a decomposition product obtained from dichloromethane, [CpMo(η 4-C 4H 6)(μ-Cl)(μ-CH 2)(O)MoCp][CH 3B(C 6F 5) 3], indicate that the borane attack has occurred at the methyl position. 相似文献
15.
The reaction of the anionic mononuclear rhodium complex [Rh(C 6F 5) 3Cl(Hpz)] t- (Hpz = pyrazole, C 3H 4N 2) with methoxo or acetylacetonate complexes of Rh or Ir led to the heterodinuclear anionic compounds [(C 6F 5) 3Rh(μ-Cl)(μ-pz)M(L 2)] [M = Rh, L 2 = cyclo-octa-1,5-diene, COD (1), tetrafluorobenzobarrelene, TFB (2) or (CO) 2 (4); M = Ir, L 2 = COD (3)]. The complex [Rh(C 6F 5) 3(Hbim)] − (5) has been prepared by treating [Rh(C 6F 5) 3(acac)] − with H 2bim (acac = acetylacetonate; H 2bim = 2,2′-biimidazole). Complex 5 also reacts with Rh or Ir methoxo, or with Pd acetylacetonate, complexes affording the heterodinuclear complexes [(C 6F 5) 3Rh(μ-bim)M(L 2)] − [M = Rh, L 2 = COD (6) or TFB (7); M = Ir, L 2 = COD (8); M = Pd, L 2 = η 3-C 3H 5 (9)]. With [Rh(acac)(CO) 2], complex 5 yields the tetranuclear complex [{(C 6F 5) 3Rh(μ-bim)Rh(CO) 2} 2] 2−. Homodinuclear Rh III derivatives [{Rh(C 6F 5) 3} 2(μ-L) 2] ·- [L 2 = OH, pz (11); OH, S tBu (12); OH, SPh (13); bim (14)] have been obtained by substitution of one or both hydroxo groups of the dianion [{Rh(C 6F 5) 3(μ-OH)} 2] 2− by the corresponding ligands. The reaction of [Rh(C 6F 5) 3(Et 2O) x] with [PdX 2(COD)] produces neutral heterodinuclear compounds [(C 6F 5) 3Rh(μ-X) 2Pd(COD)] [X = Cl (15); Br (16)]. The anionic complexes 1–14 have been isolated as the benzyltriphenylphosphonium (PBzPh 3+) salts. 相似文献
16.
Reaction of the ruthenium(IV) chloro-bridged dimer [{Ru(η 3 : η 3-C 10H 16)Cl(μ-Cl)} 2], 1, with ethanethiol (EtSH) in CH 2Cl 2 gives the bridged-cleaved adduct [Ru(η 3 : η 3-C 10H 16)Cl 2(SHEt)], 2. Stirring of two molar equivalents of 2 in methanol with one equivalent of 1 gives the binuclear, mixed chloro/thiolato bridged compound [{Ru(η 3 : η 3-C 10H 16)Cl} 2(μ-SEt)], 3. The related doubly thiolato bridged complex [{Ru(η 3 : η 3-C 10H 10)Cl(μ-SEt)} 2], 4, is formed by treatment of 1 with an excess of EtSH, or by prolonged stirring of 2 alone in methanol. Compounds 2–4 have been studied by cyclic voitammetry. Compound 2 undergoes only irreversible oxidation, whereas in the case of both 3 and 4 the observation of significant return waves is consistent with a greater stability of the primary redox products. 相似文献
17.
The acid–base chemistry of some ruthenium ethyne-1,2-diyl complexes, [{Ru(CO) 2(η-C 5H 4R)} 2(μ 2-CC)] (R=H, Me) has been investigated. Initial protonation of [{Ru(CO) 2{η-C 5H 4R}} 2(μ 2-CC)] gave the unexpected complex cation, crystallised as the BF 4 salt, [{Ru(CO) 2(η-C 5H 4R}} 3(μ 3-CC)][BF 4] (R=Me structurally characterised). This synthesis proved to be unreliable but subsequent, careful protonation experiments gave excellent yields of the protonated ethyne-1,2-diyl complexes, [{Ru(CO) 2{η-C 5H 4R)} 2(μ 2-η 1:η 2-CCH)](BF 4) (R=Me structurally characterised) which could be deprotonated in high yield to return the starting ethyne-1,2-diyl complexes. 相似文献
18.
The reaction of [ R-( R, R)]-(+) 589-[(η 5-C 5H 5){1,2-C 6H 4(PMePh) 2}Fe(NCMe)]PF 6 with (±)-AsHMePh in boiling methanol yields crystalline [ R-[( R)-( R, R)]-(+) 589)-[(η5-C5H5){1,2-C6H4(PMePh)2}Fe(AsHMePH)PF 6, optically pure, in ca. 90% yield, in a typical second-order asymmetric transformation. This complex contains the first resolved secondary arsine. Deprotonation of the secondary arsine complex with KOBu t at −65°C gives the diastereomerically pure tertiary arsenido-iron complex [ R-[( R),( R, R)]]-[((η 5-C 5H 5){1,2-C 6H 4(PMePh) 2}FeAsMePh] · thf, from which optically pure [ R-[( S),( R, R)]]-(+) 589-[(η 5-C 5H 5){1,2-C 6H 4(PMePh) 2}Fe(AsEtMePh)PF 6 is obtained by reaction with iodoethane. Cyanide displaces ( R)-(−) 589-ethylmethylphenylarsine from the iron complex, thereby effecting the asymmetric synthesis of a tertiary arsine, chiral at arsenic, from (±)-methylphenylarsine and an optically active transition metal auxiliary. 相似文献
19.
The hydroxo-complexes [{PdR(PPh 3)(μ-OH)} 2] (R = C 6F 5 or C 6Cl 5) have been obtained by reaction of the corresponding [{PdR(PPh 3)(μ-Cl)}2] complexes with NBu 4OH in acetone. In this solvent, the reaction of the hydroxo-bridged complexes with pyrazole (Hpz) and 3,5-dimethylpyrazole (Hdmpz) in 1:2 molar ratio leads to the formation of the new complexes [{Pd(C 5F 5)(PPh 3)(μ-azolate)}2] and [{Pd(C 6Cl 5)(PPh 3)} 2(μ-OH)(μ-azolate)] (azolate = pz or dmpz). The reaction of the bis(μ-hydroxo) complexes with Hpz and Hdmpz in acetone in 1:1 molar ratio has also been studied, and the resulting product depends on the organic radical (C 6F 5 or C 6Cl 5) as well as the azolate (pz or dmpz). The identity of the isomer obtained has been established in every case by NMR ( 1H, 19F and 31P) spectroscopy. The reaction of the bis(μ-hydroxo) complexes with oxalic (H 2Ox) and acetic (HOAc) acids yields the binucle ar complexes [{PdR(PPh 3)}2(μ-Ox)] (R = C 6F 5 or C 6Cl 5) and [{Pd(C 6F 5)(PPh 3)(μ-OAc)}2], respectively. [{Pd(C 6F 5)(PPh 3)(μ-OH)} 2] reacts with PPh 3 in acetone in 1:2 ratio giving the mononuclear complex trans-[Pd(C 6F 5) (OH)(PPh 3) 2], whereas the pentachlorophenylhydroxo complex does not react with PPh 3, even under forcing conditions. 相似文献
20.
The synthesis and reactivity of {(η 5-C 5H 4SiMe 3) 2Ti(CCSiMe 3) 2} MCl 2 (M = Fe: 3a; M = Co: 3b; M = Ni: 3c) is described. The complexes 3 are accessible by the reaction of (η 5-C 5H 4SiMe 3) 2Ti(CSiMe 3) 2 (1) with equimolar amounts of MCl 2 (2) (M = Fe, Co, Ni). 3a reacts with the organic chelat ligands 2,2′-dipyridyl (dipy) (4a) or 1,10-phenanthroline (phen) (4b) in THF at 25°C to afford in quantitative yields (η 5-C 5H 4SiMe 3) 2Ti(CSiMe 3) 2 (1) and [Fe(dipy) 2]Cl 2 (5a) or [Fe(phen) 2]Cl 2 (5b). 1/ n[Cu IHal] n (6) or 1/ n[Ag IHal] n (7) (Hal = Cl, Br) react with {(η 5 -C 5H 4SiMe 3) 2Ti(CCSiMe 3) 2}FeCl 2 (3a), by replacement of the FeCl 2 building block in 3a, to yield the compounds {(η 5-C 5H 4SiMe 3) 2Ti(C CSiMe 3) 2}Cu IHal (8) or {(η 5-C 5H 4SiMe 3) 2Ti(CSiMe 3) 2}Ag IHal (9) (Hal = Cl, Br), respectively. In 8 and 9 each of the two Me 3SiCC-units is η 2-coordinated to monomeric Cu I Hal or Ag IHal moieties. Compounds 8 and 9 can also be synthesized by the reaction of (η 5-C 5H 4SiMe 3) 2 Ti(CSiMe 3) 2 (1) with 1/ n[Cu IHal] n (6) or 1/ n [Ag IHal] n (7) in excellent yields. All new compounds have been characterized by analytical and spectroscopic data (IR, 1H-NMR, MS). The magnetic moments of compounds 3 were measured. 相似文献
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