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Iron complexes carbon monoxide

A related version of great economic interest is the Fischer-Tropsch process for reductive conversion of carbon monoxide to hydrocarbons. This reaction is catalyzed by a number of metals but cobalt and iron have been most closely studied. The key reaction steps are reduction of metal-complexed carbon monoxide and carbonyl insertion reactions. The hydrocarbon chain is built up by a series of successive carbonyl insertion and reduction steps. [Pg.292]

With an atomic number of 28 nickel has the electron conflguration [Ar]4s 3c (ten valence electrons) The 18 electron rule is satisfied by adding to these ten the eight elec Irons from four carbon monoxide ligands A useful point to remember about the 18 electron rule when we discuss some reactions of transition metal complexes is that if the number is less than 18 the metal is considered coordinatively unsaturated and can accept additional ligands... [Pg.608]

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. [Pg.518]

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. [Pg.519]

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. [Pg.520]

Subsequent carbonylation of the alkyl-iron complexes with carbon monoxide provides the desired chiral iron-acyl complexes, with essentially complete inversion of configuration at... [Pg.522]

An explanation of the relative oxygen and carbon monoxide affinities of some iron(II) porphyrin complexes. T. Hashimoto and F. Basolo, Comments Inorg. Chem., 1981,1,199-205 (18). [Pg.47]

Flooding. An iron-phthaloc/anine complex reacts with carbon monoxide to liberate methyl imidazole 26... [Pg.42]

It is quite possible for a metal centre to possess a zero or negative oxidation state. Thus, the species [Cr(C0)6] and [Fe(C0)4] are chromium(O) and iron(-2) complexes. We will see in a later chapter that it is not a coincidence that these low formal oxidation states are associated with ligands such as carbon monoxide. [Pg.13]

In a number of cases, alkenes that are too unstable for isolation have been isolated in the form of metal complexes. As example is norbomadienone, which was isolated in the form of its iron-tricarbonyl complex (11). The free dienone spontaneously decomposes to carbon monoxide and benzene (see 17-29). [Pg.103]

The complex [Ni(bpy)2]2+ catalyzes the electroreductive coupling of organic halides and carbon monoxide into ketones under a CO atmosphere,226 or in the presence of a metal carbonyl,227 especially iron pentacarbonyl. Unsymmetrical ketones have been obtained from mixtures of two different organic halides.228 CO is very reactive towards reduced Ni° species to form the stable [Ni°(bpy)(CO)2]° complex, which probably evolves to a transient arylnickel [Nin(bpy)(R)(CO)X]° complex in the presence of both ArX and [Ni°(bpy)]° species.229,230... [Pg.486]

HRP C contains two different types of metal center (i.e., iron(III) protoporphyrin IX-heme group and two calcium atoms) that are fundamental for the integrity of the enzyme. The heme group is attached to the enzyme at His 170 by a coordinate bond between the histidine side-chain NE2 atom and the heme iron atom. The second axial coordination site is unoccupied in the resting state of the enzyme but available to hydrogen peroxide during enzyme turnover. Small molecules such as carbon monoxide, cyanide, fluoride, and azide bind to the heme iron atom at this distal site, giving six-coordinated PX complexes. [Pg.112]

Fischer-Tropsch synthesis could be "tailored by the use of iron, cobalt and ruthenium carbonyl complexes deposited on faujasite Y-type zeolite as starting materials for the preparation of catalysts. Short chain hydrocarbons, i.e. in the C-j-Cq range are obtained. It appears that the formation and the stabilization of small metallic aggregates into the zeolite supercage are the prerequisite to induce a chain length limitation in the hydrocondensation of carbon monoxide. However, the control of this selectivity through either a definite particle size of the metal or a shape selectivity of the zeolite is still a matter of speculation. Further work is needed to solve this dilemna. [Pg.201]

Synthine [Synthetic benzin] An early version of the Fischer-Tropsch process in which a mixture of carbon monoxide and hydrogen was passed over an iron catalyst and thereby converted to a complex mixture of oxygenates. [Pg.263]

The product is exclusively carbon monoxide, and good turnover numbers are found in preparative-scale electrolysis. Analysis of the reaction orders in CO2 and AH suggests the mechanism depicted in Scheme 4.6. After generation of the iron(O) complex, the first step in the catalytic reaction is the formation of an adduct with one molecule of CO2. Only one form of the resulting complex is shown in the scheme. Other forms may result from the attack of CO2 on the porphyrin, since all the electronic density is not necessarily concentrated on the iron atom [an iron(I) anion radical and an iron(II) di-anion mesomeric forms may mix to some extent with the form shown in the scheme, in which all the electronic density is located on iron]. Addition of a weak Bronsted acid stabilizes the iron(II) carbene-like structure of the adduct, which then produces the carbon monoxide complex after elimination of a water molecule. The formation of carbon monoxide, which is the only electrolysis product, also appears in the cyclic voltammogram. The anodic peak 2a, corresponding to the reoxidation of iron(II) into iron(III) is indeed shifted toward a more negative value, 2a, as it is when CO is added to the solution. [Pg.262]


See other pages where Iron complexes carbon monoxide is mentioned: [Pg.33]    [Pg.35]    [Pg.504]    [Pg.434]    [Pg.473]    [Pg.211]    [Pg.699]    [Pg.152]    [Pg.309]    [Pg.148]    [Pg.149]    [Pg.731]    [Pg.316]    [Pg.485]    [Pg.192]    [Pg.33]    [Pg.278]    [Pg.123]    [Pg.35]    [Pg.136]    [Pg.44]    [Pg.235]    [Pg.236]    [Pg.63]    [Pg.592]    [Pg.451]    [Pg.98]    [Pg.238]    [Pg.576]    [Pg.199]    [Pg.125]    [Pg.160]    [Pg.241]    [Pg.974]    [Pg.385]   
See also in sourсe #XX -- [ Pg.1197 ]

See also in sourсe #XX -- [ Pg.4 , Pg.1197 ]




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Iron carbon monoxide

Iron carbonate

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