Reactions with derivatives of γ-chloroacetoacetic acid Ethyl γ-chloroacetoacetate reacts with ammonia to give ethyl β-amino-γ-chloro-crotonate; with aniline, however, β-anilino-crotonic acid γ-lactone is formed. The reaction of ethyl α-cyano-γ-chloro-acetoacetate with arylamines yields 1-aryl-2-amino-3-ethoxycarbonyl-pyrrolin-4-ones. 相似文献
The (η2-formaldehyde)zirconocene dimer (Cp2
H2)2 (7) inserts CO2 into the zirconium to carbon bond of the metallaoxirane moiety to give [(Cp2
H2)(Cp2
=O)] (8). Reaction with diphenylketene 7 gives the cyclodimeric 1 : 1 addition product (Cp2
=CPh2)2 (10) via the mono-insertion product 9. Similarly, treatment of 7 with t-butylisocyanate yields the intermediate complex [(Cp2
H2)(Cp2
=NCMe3)] (11) which gives the final product (Cp2
=NCMe3)2 (12). Here two five-membered metallacycles are joined together by oxygen bridges via a central four-membered Zr2O2 metallacycle. Complex 12 was characterized by X-ray diffraction. It crystallizes in space group P21/n with cell parameters a 10.142(1), b 17.949(2), c 12.001(1) Å, β = 114.27(1)°; Z = 2, R = 0.055, Rw = 0.054. 相似文献
The hydrides (η5-C5H5)(CO)3MH (M = Mo, W) react with ynamines R′CCNR2 under mild conditions to form 1 : 1 adducts. According to the 1H and 13C NMR spectra depending on the metal and the ynamine substituents carbene acyl chelate or complexes with η3-aminoacryloyl ligands are formed: A Dicarbene chelate compound is obtained by alkylation of I, R = Et, R′ = Me. CC-η2 keteneimmonium complexes are formed in the reaction of the phosphite substituted hydrides (η5-C5H5)(CO)2P(OMe)3MH (M = Mo, W) with MeCCN Et; an intermediate 1-aminovinyl compound has been isolated. 相似文献
The condensation of α,α-dichloropropionyl chloride (IVa) and of trichloroacetyl chloride (IVb) with α-chloropropionyl chloride (Ia) in the presence of triethylamine led to two acid chloride enol-esters, both as mixtures of cis- and trans-isomers, namely 1, 2-dichloropropenyl α,α-dichloropropionate (Va) and 1, 2-dichloropropenyl trichloroacetate (Vb). A mixture of triethylamine and trichloroacetyl chloride produced an oxidation-reduction reaction to give 48% 1, 2, 2, 2-tetrachloroethyltrichloroacetate (VIII) and 69% 1-diethylamino-4, 4, 4-trichloro-1-butene-3-one (IX). Basic hydrolysis of IX led to 43% of glutaconic acid (XIII). Tripropylamine reacted in the same way with trichloroacetyl chloride to yield 1-dipropylamino-2-methyl-4, 4, 4-trichloro-but-1-ene-3-one (XIX) which was readily hydrolyzed in acid solution to α-trichloroacetyl-propionaldehyde (XX). 相似文献
The reaction of imidoylzirconocene complexes with zirconocene hydrides yields (N-alkylamido)zirconocene complexes. For a mechanistic study, the specifically substituted imidoylzirconocene complexes 3b–3d have been prepared and treated with the oligomeric metal hydrides (Cp2ZrH2)x (1b) and (Cp2ZrHCl)x (1c). (N-Benzyl formimidoyl)zirconocene chloride (3b) was obtained by treating 1c with benzyl isonitrile 2a. Treatment of dimethylzirconocene with 2a gave (N-benzyl acetimidoyl)methylzirconocene (3c), which was treated with PhICl2 to give (N-benzylacetimidoyl)zirconocene chloride (3d). The reaction of 3d with (Cp2ZrH2)x (1b) yielded (N-benzyl-N-ethylamido)zirconocene chloride (4b) as the only identified product. A 1/1 mixture of 4b and methylzirconocene chloride was obtained upon treatment of 3c with (Cp2ZrHCl)x (1c); in contrast, the reaction of 1c with 3b gave an equimolar mixture of Cp2ZrCl2 and (N-benzyl-N-methylamido)zirconocene chloride (4c). Reaction paths through binuclear (μ-CHR′=NR) zirconocene intermediates are proposed to explain these experimental observations. 相似文献
Tricarbonyl(fulvene)chromium complexes react with anionic nucleophiles to give functionally substituted cyclopentadienyl derivatives. The nucleophilic attack occurs at the exocyclic carbon atom of the fulvene ligand. Addition of PPh2− to (η6-6,6-dimethylfulvene)Cr(CO)3 (1) yields the novel anion [(η5-C5H4C(CH3)2PPh2)Cr-(CO)3]−, which can be isolated as a K+, (C2H5)4N+, (C6H5)4P+, or Tl+ derivative (2–5). The potassium salt of the uncoordinated C5H4C(CH3)2PPh2− anion (7) is obtained by treatment of 6,6-dimethylfulvene with KPPh2·2C4H8O2. Similarly, NaC5H5 reacts with 1 to give Na[(η5-C5H4C(CH3)2C5H5)Cr(CO)3] (8). The reactions of (6-dimethylaminofulvene)Cr(CO)3 (15) with nucleophiles are accompanied by elimination of dimethylamine. Addition of Ph3P=CH2 to 15 gives an unstable product, but after reaction of 6-dimethylaminofulvene with Ph3P=CH2, the free ligand C5H4=CHCH=PPh3 (17) can be isolated in moderate yields. Deeply colored anions of the type [(η5:η5-C5H4C(R)=C5H4)Cr2(CO)6]− (R = H, N(CH3)2) are synthesized by reaction of 15 or (6-dimethylamino-6-methylthiofulvene)Cr(CO)3 with NaC5H5 and subsequent complexation of the mononuclear intermediate with (CH3CN)3Cr(CO)3. In addition, the synthesis of the new fulvene complexes [C5H4=CH(CH=CH)2N(CH3)Ph]M(CO)3 (23, 24; M = Cr, Mo) is described. The investigation is extended to α-ferrocenylcarbenium ions, which are isoelectronic with (fulvene)Cr(CO)3 complexes. [(η5-C5H5)Fe(C5H4CPh2)]+ BF4− (25) adds tertiary phosphines at the exocyclic carbon atom to give phosphonium salts of the type [(η5-C5H5)Fe(C5H4CPh2PR3)]+BF4−. A CO-substititution product of a tricarbonyl (fulvene)chromium complex is obtained for the first time by irradiation of (η6-6,6-diphenylfulvene)Cr(CO)3 in the presence of PPh3. In addition, an improved synthesis of the (CH3CN)3M(CO)3 complexes (M = Cr, Mo, W) is reported. 相似文献
Reactions of the Cycloheptatrienyl Complexes [η7-C7H7W(CO)3]BF4 and η7-C7H7Mo(CO)2Br with Neutral Ligands and the Electrochemical Reduction of the Wolfram Complex Compounds of the type [η7-C7H7M(CO)2L][BF4] (L = P(C6H5)3, As(C6H5)3, Sb(C6H5)3 for M = W and L = N2H4 for M = Mo) were synthesized and characterisized. The iodide η7-C7H7W(CO)2I reacts with the diphosphine ((C6H5)2PCH2)2 to give the trihapto complex η3-C7H7 W(CO)2I((C6H5)2PCH2)2. In the case of η7-C7H7Mo(CO)2 Br reaction with hydrazine leads to the substitution product [η7-C7H7 Mo(CO)2N2H4]⊕, which can be stabilized by large anions. The binuclear complex [C7H7W(CO)3]2 has been synthesized electrochemically. 相似文献
trans-I(CO)2L2WCNEt2 complexes (L2 = 2,2′-bipyridyl (2,2′-bipy); 1,10-phenanthroline (ophen)) react with PR3 (R = Me, Et) and thus undergo substitution of the iodine ligand by the phosphine to yield the new, thermostable, cationic carbyne complexes, [(PR3)(CO)2L2WCNEt2]+ I−. The ionic character of the compounds has been established from electrical conductivity studies of their solutions. Spectroscopic investigations of the complexes, whose composition has been determined by elemental analysis, indicate that in this reaction the halogen ligand in the trans position has been displaced by the chelate ligand, while the phosphine ligand occupies a cis coordination site, relative to carbyne moiety. 相似文献
Reactions of π-Organonickel Complexes with Tertiary Phosphanes In a hexane solution Ni(C5H5)2 reacts with PBu3 or Ph2PBu forming the nickel(O) complexes Ni(PBu3)4 or Ni(Ph2PBu)4 (A). Under the same conditions only one cyclopentadienyl ligand is substituted by PhPBu2 and the nickel(I) compound (C5H5)Ni (PhPBu2)2 (B) is obtained. Products of the reactions between B and α,α′-dipyridyl, hydrogen chlorid in ether, or Ni(PhPBu2),Cl2 are Ni(dipy)2, [PhPHBu2]2[NiCl4], or (C5H5) Ni(PhPBu2)2Cl. By the reaction with HgCl2 a cyclopentadienyl compound of an unknown structur is formed. The compound Ni(PhPBu2)4 which is analogous to A is synthesized by the reduction of bis(acety1acetonato)-nickel with Et2AlOEt in the presence of PhPBu2 or by the reaction of bis (cyclooctadiene-1,5)-nickel with PhPBu2. 相似文献
