Iron acyl complex

I.3.4.2.5. Chiral Enolates of Acyl-Metal Complexes J. S. McCallum and L. S. Liebeskind I.3.4.2.5.I. Chiral Iron-Acyl Complexes... 

The commercially available (tj5-cyclopentadienyl)iron dicarbonyl dimer 1 is the source of the carbonyl(//5-cyclopentadienyl)iron(L) moiety. Reductive or oxidative cleavage of 1 provides reactive monomeric species that may be converted into iron-acyl complexes as described in the following sections (see also Houben-Weyl, Vol. 13/9a, p208). 

Alkylation of the anion 2 with iodomethane or other haloalkanes provides alkyldicarbonyl(t/5-cyclopentadienyl)iron complexes such as 53,0 (see also Houben-Weyl, Vol. 13/9a, p 209). Migratory insertion of carbon monoxide occurs on treatment with phosphanes or phosphites9 -11 (see also Houben-Weyl, Vol. d3/9a, p257) to provide chiral iron-acyl complexes such as 6. This is the most commonly used preparation of racemic chiral iron-acyl complexes. 

The a-alkoxy-substituted iron-acyl complex 8 is prepared by oxidation of the enolate prepared from iron-acetyl complex 6 and subsequent etherification12. 

Enantiomerically Pure Chiral Iron-Acyl Complexes... 

The reported preparations of enantiomerically pure chiral iron-acyl complexes have relied upon resolutions of diastereomers. One route1415 (see also Houben-Weyl, Vol. 13/9 a, p 421) employs a resolution of the diastereomeric acylmenlhyloxy complexes (Fe/ )-3 and (FeS )-3 prepared via nucleophilic attack of the chiral menlhyloxide ion of 2 at a carbon monoxide of the iron cation of 1. Subsequent nucleophilic displacement of menthyloxide occurs with inversion at iron to generate the enantiomerically pure iron-acyl complexes (i>)-4 and (f )-4. 

Another route to enantiomcrically pure iron-acyl complexes depends on a resolution of diastereomeric substituted iron-alkyl complexes16,17. Reaction of enantiomerically pure chloromethyl menthyl ether (6) with the anion of 5 provides the menthyloxymethyl complex 7. Photolysis of 7 in the presence of triphenylphosphane induces migratory insertion of carbon monoxide to provide a racemic mixture of the diastereomeric phosphane-substituted menthyloxymethyl complexes (-)-(/ )-8 and ( + )-( )-8 which are resolved by fractional crystallization. Treatment of either diastereomer (—)-(/J)-8 or ( I )-(.V)-8 with gaseous hydrogen chloride (see also Houben-Weyl, Vol 13/9a, p437) affords the enantiomeric chloromethyl complexes (-)-(R)-9 or (+ )-(S)-9 without epimerization of the iron center. 

Subsequent carbonylation of the alkyl-iron complexes with carbon monoxide provides the desired chiral iron-acyl complexes, with essentially complete inversion of configuration at... 

Hydroxy-substituted iron-acyl complexes 1, which are derived from aldol reactions of iron-acyl enolates with carbonyl compounds, are readily converted to the corresponding /i-methoxy or /1-acetoxy complexes 2 on deprotonation and reaction of the resulting alkoxide with iodomethane or acetic anhydride (Tabic 1). Further exposure of these materials to base promotes elimination of methoxide or acetate to provide the a,/ -unsaturated complexes (E)-3 and (Z)-3 (Table 2). 

Table 2. x./TUnsaturated Iron-Acyl Complexes 3 from 2 via Elimination Reactions CFe R1 base/THF [FeL R1 [Fe] ... 

Aldol reaction of the a-trimethylsilylated enolate 9 with aldehydes provides nearly equal amounts of chromatographically separable ( )- and (Z)-isomers of iron-acyl complexes 11 via silyloxide elimination from the intermedate aldolate 10 (Table 3). This methodology has been the most commonly employed entry to the (Z)-isomer series. 

Table 3. Iron-Acyl Complexes 11 from CarbonyUr/ -acyclopentadienylHl-oxo -ftriinethylsilyllethyl] (triphenylphosphane)iron (8) by the Aldol Reaction with Aldehydes...

The lithium enolate 2a (M = Li ) prepared from the iron propanoyl complex 1 reacts with symmetrical ketones to produce the diastercomers 3 and 4 with moderate selectivity for diastereomer 3. The yields of the aldol adducts are poor deprotonation of the substrate ketone is reported to be the dominant reaction pathway45. However, transmetalation of the lithium enolate 2a by treatment with one equivalent of copper cyanide at —40 C generates the copper enolate 2b (M = Cu ) which reacts with symmetrical ketones at — 78 °C to selectively produce diastereomer 3 in good yield. Diastereomeric ratios in excess of 92 8 are reported with efficient stereoselection requiring the addition of exactly one equivalent of copper cyanide at the transmetalation step45. Small amounts of triphcnylphosphane, a common trace impurity remaining from the preparation of these iron-acyl complexes, appear to suppress formation of the copper enolate. Thus, the starting iron complex must be carefully purified. 

Conducting the aldol reaction at temperatures below —78 "C increases the diastereoselectivity, but at the cost of reduced yields45. Transmetalation of the lithium enolate 2 a by treatment with diethylaluminum chloride generated an enolate species that provided high yields of aldol products, however, the diastereoselectivity was as low as that of the lithium species45. Pre treatment of the lithium enolate 2a with tin(II) chloride, zinc(II) chloride, or boron trifluoridc suppressed the aldol reaction and the starting iron-acyl complex was recovered. 

The a-alkoxy iron-acyl complex 5 may be deprotonated to generate the lithium enolate 6, which undergoes a highly diastereoselective aldol reaction with acetone to generate the adduct 7 as the major product. Deprotonation of acetone by 6 is believed to be a competing reaction 30% of the starting complex 5 is found in the product mixture48 40. 

The lithium enolate of the oc-silyl-substituted iron-acyl complex 19 reacts with aldehydes, however, products of the Peterson elimination process (E)- and (Z)-22 are usually isolat-ed22- 23,36.37 for t[1js anc other preparations of a,/t-unsaturated iron-acyl complexes see Section I.3.4.2.5.I.3.). 

Table 5. Carboxylic Acids 5 by Removal of the Chiral Auxiliary from Iron-Acyl Complexes 4...

Oxidative decomplexation of iron acyl complexes in the presence of alcohols provides the corresponding carboxylates 7. Usual conditions employ ca. 7% alcohol in dichloromethane or dichloromethane/carbon disulfide as the solvent with bromine as the oxidant. 

Amides are produced if iron - acyl complexes are oxidized in the presence of a secondary or primary amine25 52 59 60. This reaction, usually conducted at low temperatures, employs /Y-bromosucciniinide or bromine as the oxidant (see Table 6). 

The oxidation of /(-amino-substituted iron acyl complexes which are prepared via condensation reactions of iron-acyl enolates and imines or iminium ions26,5 -47-54 generates /(-lactams 32,33,61. Brief treatment with bromine in dichloromethane at low temperature is the usual procedure. 

Treatment of a-alkoxy-substituted iron acyl complexes 20 with bromine in the presence of an alcohol produces free acetals 22 with loss of stereochemistry at the center derived from the a-carbon of the starting complexl2,49. Electron donation from the alkoxy group allows formation of the oxonium intermediate 21, which is captured by the alcohol to generate the product acetal. 

Enolate Preparation by Deprotonation of Iron-Acyl Complexes a-Deprotonation of Iron-Acyl Complexes... 

Strong bases are required to abstract an a-proton from iron-acyl complexes (see also Houben-Weyl, Volume 13/9a, p 417). Such deprotonations are usually conducted in moderately polar solvents such as tetrahydrofuran. The archetypal complexes 1 and 2 illustrate most of the factors influencing a-proton abstraction. 

The anion 7 is quite nucleophilic and undergoes exclusive C-alkylation upon reaction with electrophiles including chlorotrimethylsilane °. These reactivity patterns have led to the suggestion that enolates of iron-acyl complexes may be considered to behave similarly to the organic dianion 910- u. 

Most of the work in this area has concerned complexes racemic at iron. Section D.1.3.4.2.5.1.1. details methods for the preparation and resolution of enantiomerically pure iron acyl complexes. The details of alkylation reactions (see Section 1.1.1.3.4.1.3.) and aldol reactions (see Section 1.3.4.2.5.1.2.) of these and other iron acyl enolates are presented later with examples utilizing enantiomerically pure complexes indicated therein. Table 1 illustrates the scope of iron-acyl enolates prepared by deprotonation of complex 10 and its analogs. 

Treatment of the potentially electrophilic Z-xfi-unsaturated iron-acyl complexes, such as 1, with alkyllithium species or lithium amides generates extended enolate species such as 2 products arising from 1,2- or 1,4-addition to the enone functionality are rarely observed. Subsequent reaction of 2 with electrophiles results in regiocontrolled stereoselective alkylation at the a-position to provide j8,y-unsaturated products 3. The origin of this selective y-deproto-nation is suggested to be precoordination of the base to the acyl carbonyl oxygen (see structures A), followed by proton abstraction while the enone moiety exists in the s-cis conformation23536. 

Conditions employed for the generation of extended enolates by y-deprotonation of Z-oc,/ -un-saturated iron-acyl complexes are presented in Table 3. 

Reaction of Z-a./j-unsaturated iron-acyl complexes with bases under conditions similar to those above results in exclusive 1,4-addition, rather than deprotonation, to form the extended enolate species. However, it has been demonstrated that in the presence of the highly donating solvent hexamethylphosphoramide, y-deprotonation of the -complex 6 occurs. Subsequent reaction with electrophiles provides a-alkylated products such as 736 this procedure, demonstrated only in this case, in principle allows access to the a-alkylatcd products from both Z- and it-isomers of a,/j-unsaturated iron-acyl complexes. The hexamethylphosphoramide presumably coordinates to the base and thus prevents precoordination of the base to the acyl carbonyl oxygen, which has been suggested to direct the regioselective 1,4-addition of nucleophiles to -complexes as shown (see Section 1.1.1.3.4.1.2.). These results are also consistent with preference for the cisoid conformations depicted. 

Iron acyl complexes bearing an a,/ -unsaturated acyl ligand possess multiple sites of electrophilic reactivity. Strong bases may be induced to react with the acyl ligand, and in Section 1.1.1.3.4.1.1. the chemoselective y-deprotonation of Z-a,/i-unsaturated acyl ligands to generate enolate species was addressed. The profoundly different reactivity of the unsubstituted complex 1 and E-a,/ -unsaturated acyl complexes, such as 2, is discussed here. 

The range of carbon nucleophiles that have been successfully employed for 1,4-addition to -a,/i-unsaturated iron-acyl complexes is limited to simple alkyl- and aryllithium species. Grignard reagents and the 1,3-propanedioate anion are reported to fail to react with. E-complexes36. The effect of varying the phosphane ligand has been examined little effect upon... 

Representative examples of enolates produced by 1,4-addition of alkyllithium reagents to E-a,/ -unsaturated iron-acyl complexes are presented in Table 4. 

Methods for the preparation of the requisite -2,/l-unsaturaied iron-acyl complexes are presented in Section D.1.3.4.2.5., but it is noted here that several examples of 1,4-alkylative preparations of a-enolates from in situ generated fi-complexes, such as 9, have been reported in which the alkyllithium base employed acts both as a base to produce the unsaturated species via elimination and subsequently, as a nucleophile to afford alkylation products 10 and 1244. 

The more functionalized /Ta,/ -unsaturated iron-acyl complexes, such as 6, also react regiose-lectively in Michael fashion with amine anions, including the relatively non-nucleophilic lithium diisopropylamide. Stereoselective attack upon the s-cis conformer of 6 by the amine anion from the less hindered face of the inducing iron center generates the fs-cnolatc 7 which may be quenched diastereoselectively (Section 1.1.1.3.4.1.3.). 

Table 6. Alkylation of a-Enolates 2 of Chiral Iron-Acyl Complexes 1 by Carbon Electrophiles...

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