Iron complexes substitution reactions

Scheme3.7 Formation of a silyl-substituted butatrienylidene iron complex by reaction of [FeCI(Cp )(dppe)j with trimethylsilyl butadiyne.

Access to alkyl substituted derivatives of the homotropylidene complexes is provided via the >j4-tropone iron complex by reaction with diazoalkanes, followed by mild thermolysis of the 3+2 py razoline adduct to give the corresponding homotropone complexes (equation 149)217,218. The 8,8-dimethyl derivative was used as starting material for the preparation of the fluxional ( 5-2,8,8-trimethylbicyclo[5.1.0]octa-2,4-dienylium)Fe(CO)3 cation complex219. More recently (homotropone)Fe(CO)3 was used for the synthesis of unique chiral 1,2-homoheptafulvene iron complexes220 221. 

A third and very practical alternative is the resolution of racemic acyliron complexes by crystallization with (5)-(+)- or (/ )-(-)-camphersulfonic acid via the diastereomeric hydroxycarbene salts and subsequent neutralization. Conversion of the enantiomerically pure acetyliron complexes to a-alkoxy complexes and subsequent trimethylsilyl triflate-mediated removal of the methoxy group provides enantiomerically pure (ethylidene)iron complexes.Methylation of alkynoyliron complexes with Meerwein s salt has been reported to give cationic methoxy-substituted alkynylcarbenes, which can be transformed into the corresponding (aminocarbene)iron complexes upon reaction with primary amines. " Meerwein s salt can also be used to form cationic... 

Using an acetoxy function as leaving group a to the (t -diene)iron complex, this reaction has been employed for the synthesis of the C7-C24 segment of macrolactin 1-Ethoxy-substituted T) -cyclohexadienyliumiron complexes can also be obtained by alkylation of (Ti -cyclohexadienone)iron complexes with triethyloxonium cations (Scheme 4-162). Another general approach to ri -dienyliumiron complexes proceeds via protonation of a noncomplexed double bond in [(l-4-Ti)-l,3,5-triene]iron complexes (Scheme 4-163). - ... 

Alkenes in (alkene)dicarbonyl(T -cyclopentadienyl)iron(l+) cations react with carbon nucleophiles to form new C —C bonds (M. Rosenblum, 1974 A.J. Pearson, 1987). Tricarbon-yi(ri -cycIohexadienyI)iron(l-h) cations, prepared from the T] -l,3-cyclohexadiene complexes by hydride abstraction with tritylium cations, react similarly to give 5-substituted 1,3-cyclo-hexadienes, and neutral tricarbonyl(n -l,3-cyciohexadiene)iron complexes can be coupled with olefins by hydrogen transfer at > 140°C. These reactions proceed regio- and stereospecifically in the successive cyanide addition and spirocyclization at an optically pure N-allyl-N-phenyl-1,3-cyclohexadiene-l-carboxamide iron complex (A.J. Pearson, 1989). 

Diels-Alder reactions, 4, 842 flash vapour phase pyrolysis, 4, 846 reactions with 6-dimethylaminofuKenov, 4, 844 reactions with JV,n-diphenylnitrone, 4, 841 reactions with mesitonitrile oxide, 4, 841 structure, 4, 715, 725 synthesis, 4, 725, 767-769, 930 theoretical methods, 4, 3 tricarbonyl iron complexes, 4, 847 dipole moments, 4, 716 n-directing effect, 4, 44 2,5-disubstituted synthesis, 4, 116-117 from l,3-dithiolylium-4-olates, 6, 826 electrocyclization, 4, 748-750 electron bombardment, 4, 739 electronic deformation, 4, 722-723 electronic structure, 4, 715 electrophilic substitution, 4, 43, 44, 717-719, 751 directing effects, 4, 752-753 fluorescence spectra, 4, 735-736 fluorinated derivatives, 4, 679 H NMR, 4, 731 Friedel-Crafts acylation, 4, 777 with fused six-membered heterocyclic rings, 4, 973-1036 fused small rings structure, 4, 720-721 gas phase UV spectrum, 4, 734 H NMR, 4, 7, 728-731, 939 solvent effects, 4, 730 substituent constants, 4, 731 halo... 

The following compounds have been obtained from thiete 1,1-dioxide Substituted cycloheptatrienes, benzyl o-toluenethiosulfinate, pyrazoles, - naphthothiete 1,1-dioxides, and 3-subst1tuted thietane 1,1-dioxides.It is a dienophile in Diels-Alder reactions and undergoes cycloadditions with enamines, dienamines, and ynamines. Thiete 1,1-dioxide is a source of the novel intermediate, vinylsulfene (CH2=CHCH=SQ2). which undergoes cyclo-additions to strained olefinic double bonds, reacts with phenol to give allyl sulfonate derivatives or cyclizes unimolecularly to give an unsaturated sultene. - Platinum and iron complexes of thiete 1,1-dioxide have been reported. 

The iron complex 16 in anhyd benzene was treated with an alkyl halide (excess) and anhyd NaHC03 (1 mol equiv) and the mixture was stirred at 20 "C for 20 h. For acylation, an acyl chloride (1 mol equiv) and anhyd NaHCO, were employed and the mixture was stirred at 20CC for 1-2 h. For decomplexation, the TV-substituted iron complex 17 and a 20-fold molar excess of freshly sublimed Me3NO in acetone were stirred for 20 h at 20 C and the reaction mixture was worked up by chromatography to give 18. 

This is an example of a substitution reaction, a reaction in which one 1 ewis base takes the place of another. Here the CN ions drive out H20 molecules from the coordination sphere of the [Fe(H20)6]2+ complex and take their place. Replacement is less complete when certain other ions, such as Cl, are added to an iron(II) solution ... 

Iron hydride complexes can be synthesized by many routes. Some typical methods are listed in Scheme 2. Protonation of an anionic iron complex or substitution of hydride for one electron donor ligands, such as halides, affords hydride complexes. NaBH4 and L1A1H4 are generally used as the hydride source for the latter transformation. Oxidative addition of H2 and E-H to a low valent and unsaturated iron complex gives a hydride complex. Furthermore, p-hydride abstraction from an alkyl iron complex affords a hydride complex with olefin coordination. The last two reactions are frequently involved in catalytic cycles. 

The direct reductive amination (DRA) is a useful method for the synthesis of amino derivatives from carbonyl compounds, amines, and H2. Precious-metal (Ru [130-132], Rh [133-137], Ir [138-142], Pd [143]) catalyzed reactions are well known to date. The first Fe-catalyzed DRA reaction was reported by Bhanage and coworkers in 2008 (Scheme 42) [144]. Although the reaction conditions are not mild (high temperature, moderate H2 pressure), the hydrogenation of imines and/or enam-ines, which are generated by reaction of organic carbonyl compounds with amines, produces various substituted aryl and/or alkyl amines. A dihydrogen or dihydride iron complex was proposed as a reactive intermediate within the catalytic cycle. 

With the iron atom in its most negative oxidation state of —2 this complex possesses nucleophilic properties and thus can be used in nucleophilic substitution reactions. As the iron atom in this complex formally has ten valence electrons, it is isoelectronic with Pd(0), which is a well-known catalyst in allylic substitution reactions [49]. 

Although there are some reactions that use complex 76 stoichiometrically [50-58], it was not until 1979 that Roustan et al. developed the first catalytic application of complex 76-Na (Scheme 16) [59, 60]. In his publication, he could show that catalytic amounts of complex 76-Na react with an allylic chloride or acetate to form an allyl-iron-complex, which, in a second step, is substituted with a malonate to yield 77. Most importantly, they observed a preference for the ipso-substitution-product 77a, that is, the new C-Nu-bond was formed preferentially at the carbon atom that was substituted with the leaving group before. 

The thermal decomposition of iron complexes leading to the formation of different ferrites (MFe204, M = Fe, Co, Mn, etc.) is one of the most commonly used protocols to obtain magnetic NPs with control of size and shape [39]. However, some of them cannot be considered as green processes since the iron precursor, the Fe(CO)5 complex, is expensive, toxic, and flammable. Therefore, researchers have looked for non-toxic and less expensive iron precursors to be used in the thermal decomposition reactions. The first precursor in substitution of Fe(CO)5 was the FeCup3... 

In contrast to the reaction of an i72-CS2-rhodium complex with dimethyl acetylenedicarboxylate which gives rise to a metallocycle,186 the iron complexes 103 are converted by activated acetylenes into air-sensitive carbene complexes 104. Decomposition of the latter in air provides an unusual synthetic route to substituted tetrathiofulvene derivatives (Scheme 121).187... 

In marked contrast to the results of Gassman and Schrock, major differences were noted by Casey and co-workers in a series of studies utilizing phenylcarbene-substituted W(0) complexes in reactions with olefins. The H NMR spectra of new phenylcarbene tungsten and iron (69) complexes indicate a substantial positive charge residing on the carbene carbon, and as expected, these complexes readily form ylides on reaction with phosphines ... 

As part of ongoing research into the behavior of (vinylcarbene)iron complexes,119120 Mitsudo and Watanabe found that the trifluoromethyl-substituted vinylcarbene 174 exhibited a reactivity different from that of both 166 and 169.107 Upon treatment of the complex 174 with triphenylphos-phine the vinylketene complex 175 is formed, a reaction identical to that seen in the series of vinylcarbene complexes 166 (R = H). However, when the vinylcarbene 174 is exposed to a high pressure of carbon monoxide, it is converted cleanly to the ferracyclopentenone 176. Remember that when the vinylcarbene complex 166 (R = H) was treated in the same manner, conversion stopped at the vinylketene complex 167 Even when exposed to a pressure of 80 atmospheres of CO(g), no further reaction was seen to occur. An electron donating ligand (L = PR3) is required for conversion to cyclopentenone structure 168. Conversely, when the more electron-rich vinylcarbene 169 is exposed to carbon monoxide in the same manner, the pyrone complex 172 is formed. 

The reaction of the complex salt 6a with the arylamine 12 affords by regio-selective electrophilic substitution the iron complex 13 [88] (Scheme 11). The oxidative cyclization of complex 13 with very active manganese dioxide provides directly mukonine 14, which by ester cleavage was converted to mukoeic acid 15 [89]. Further applications of the iron-mediated construction of the carbazole framework to the synthesis of 1-oxygenated carbazole alkaloids include murrayanine, koenoline, and murrayafoline A [89]. 

The total synthesis of the carbazomycins emphasizes the utility of the iron-mediated synthesis for the construction of highly substituted carbazole derivatives. The reaction of the complex salts 6a and 6b with the arylamine 20 leads to the iron complexes 21, which prior to oxidative cyclization have to be protected by chemoselective 0-acetylation to 22 (Scheme 13). Oxidation with very active manganese dioxide followed by ester cleavage provides carbazomycin B 23a [93] and carbazomycin C 23b [94]. The regioselectivity of the cyclization of complex 22b to a 6-methoxycarbazole is rationalized by previous results from deuterium labeling studies [87] and the regiodirecting effect of the 2-methoxy substituent of the intermediate tricarbonyliron-coordinated cyclo-hexadienylium ion [79c, 79d]. Starting from the appropriate arylamine, the same sequence of reactions has been applied to the total synthesis of carbazomycin E (carbazomycinal) [95]. 

The carbazole-1,4-quinol alkaloids are also accessible by the iron-mediated arylamine cyclization (Scheme 14). Electrophilic substitution reaction of the arylamine 24 with the complex salts 6a and 6b affords the iron complexes 25. Protection to the acetates 26 and oxidative cyclization with very active manganese dioxide leads to the carbazoles 27, which are oxidized to the carbazole-... 

More recently, an environmentally benign method using air as oxidant has been developed for the oxidative cyclization of arylamine-substituted tricarbonyl-iron-cyclohexadiene complexes to carbazoles (Scheme 19). Reaction of methyl 4-aminosalicylate 45 with the complex salt 6a affords the iron complex 46, which on oxidation in acidic medium by air provides the tricarbonyliron-complexed 4a,9a-dihydrocarbazole 47. Aromatization with concomitant demetalation by treatment of the crude product with p-chloranil leads to mukonidine 48 [88]. The spectral data of this compound are in agreement with those reported by Wu[22j. 

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