Metal carbonyls reaction with nitriles

Recently the unprecedented example of stereoselective C—Si bond activation in cu-silyl-substituted alkane nitriles by bare CQ+ cations has been reported by Hornung and coworkers72b. Very little is known of the gas-phase reactions of anionic metal complexes with silanes. In fact there seems to be only one such study which has been carried out by McDonald and coworkers73. In this work the reaction of the metal-carbonyl anions Fe(CO) (n = 2, 3) and Mn(CO) (n = 3, 4) with trimethylsilane and SiH have been examined. The reactions of Fe(CO)3 and Mn(CO)4 anions exclusively formed the corresponding adduct ions via an oxidative insertion into the Si—H bonds of the silanes. The 13- and 14-electron ions Fc(CO)2 and Mn(CO)3 were observed to form dehydrogenation products (CO) M(jj2 — CH2 = SiMe2) besides simple adduct formation with trimethylsilane. The reaction of these metal carbonyl anions with SiFLj afforded the dehydrogenation products (CO)2Fe(H)(SiII) and (CO)3Mn(II)(SiII). ... 

The synthesis of a,p-unsaturated carbonyl compounds and nitriles by Pd-catalyzed reaction [245] of allyl p-oxo esters and allyl a-cyano esters is an oxidative process. With the contra-polarizability of the metal ion, elimination of a hydride from the p-position is electronically favorable. 

Zirconium and hafnium dialkylamides are highly reactive compounds. They undergo (i) protolytic substitution reactions with reagents such as alcohols, cyclopentadiene and bisftrimethylsilyOamine 63 64 (ii) insertion reactions with C02, CS2, COS, nitriles, phenyl isocyanate, methyl isothiocyanate, carbodiimides and dimethyl acetylenedicarboxylate 69-72 and (iii) addition reactions with metal carbonyls.73 These reactions are summarized with reference to Zr(NMe2)4 in Scheme 1. 

Cyclopropane formation occurs from reactions between diazo compounds and alkenes, catalyzed by a wide variety of transition-metal compounds [7-9], that involve the addition of a carbene entity to a C-C double bond. This transformation is stereospecific and generally occurs with electron-rich alkenes, including substituted olefins, dienes, and vinyl ethers, but not a,(J-unsaturated carbonyl compounds or nitriles [23,24], Relative reactivities portray a highly electrophilic intermediate and an early transition state for cyclopropanation reactions [15,25], accounting in part for the relative difficulty in controlling selectivity. For intermolecular reactions, the formation of geometrical isomers, regioisomers from reactions with dienes, and enantiomers must all be taken into account. 

The amide ions are powerful bases and may be used (i) to dehydrohalogenate halo-compounds to alkenes and alkynes, and (ii) to generate reactive anions from terminal acetylenes, and compounds having reactive a-hydrogens (e.g. carbonyl compounds, nitriles, 2-alkylpyridines, etc.) these anions may then be used in a variety of synthetic procedures, e.g. alkylations, reactions with carbonyl components, etc. A further use of the metal amides in liquid ammonia is the formation of other important bases such as sodium triphenylmethide (from sodamide and triphenylmethane). 

In the same way that we were primarily concerned with reactions of nitriles in the previous section, we will be concerned with the attack of nucleophiles on imines in this section. Imines, R2C=NR, are the nitrogen analogues of carbonyl groups, and we saw in Chapter 2 that imines may be stabilised by co-ordination to a metal ion capable of back-donation to the ligand -levels. We shall investigate the synthetic utility associated with the formation of co-ordinated imines in a later chapter. However, it is also possible to promote the hydrolysis of the imine by co-ordination to a positively charged metal ion. 

This chelation-assisted C-H/olefin and C-H/acetylene coupling can be applied to a variety of aromatic compounds with a directing group such as ester, aldehyde, imine, azo, oxazolyl, pyridyl, and nitrile [7]. In this section, we describe the coupling reactions of aromatic carbonyl compounds with olefins using a transition metal catalyst. 

Nitrile derivatives of the metal carbonyls have been discussed together with other nitrogen donor molecules in a number of contexts. Much of the early work has been reviewed by Manuel 337) in his article on Lewis base-metal carbonyl complexes in Volume 3 of this series, and by Stroh-meier 436) in his review of photochemical substitution reactions. In general, nitriles are weaker Lewis donors than phosphorus and nitrogen bases 436), but compared to carbon monoxide, better electron donors but poorer acceptors 427). Force constants and assignments for a series of complexes [(MeCN)jjM(CO)g J (M = Cr, Mo, W) were studied 165, 228, 296) and... 

Nitrile complexes may be synthesized by the thermal reaction of the parent carbonyl with the appropriate nitrile, but elevated temperatures are required, and this often leads to complications of thermal decomposition and/or further reaction. A more controlled route widely used is the irradiation of the metal carbonyl in a solution of the nitrile, or in a donor solvent capable of forming a labile complex such as Cr(CO),THF. Addition of the nitrile displaces the weakly bound solvent molecule 172, 248). 

The uranium-carbon multiple bond has an extensive insertion chemistry with polar unsaturated molecules including carbon monoxide, nitriles, isocyanides,and isocyanates. Metal carbonyls also insert into this bond to form metallaphosphoniumenolates, which undergo novel reactions... 

Transition metal carbonyls such as Co2(CO)8 and CoH(CO)4, formed in the reaction of R3SiH with dimer (but also Fe(CO)5 and M3(CO)i2 (M = Fe, Ru, Os)) have been found to be active catalysts for the hydrosilylation of olefins, dienes, unsaturated nitriles, and esters as well as for hydrosilylation C=0 and C=N bonds [56]. Hydrosilylation of phenylthioacetylenes in the presence of this catalyst is extremely regioselective [57]. Cobalt(I) complexes, e. g., CoH(X)2L3 (X = H, N), could be prospective candidates for investigation of the effectiveness of alkene hydrosilylation by trialkoxysilanes as well as dehydro-genative silylation [58]. Direct evidence for the silyl migration mechanism operative in a catalytic hydrosilylation pathway was presented by Brookhart and Grant [59] using the electrophilic Co cationic complex. 

Reaction of Methanol with Carbonyl Compounds. - Similar to the reaction of methanol with carboxylic acid, esters, or nitriles shown in Sections 5.2 and 6.2, attempts were made to use the HCHO which is formed by dehydrogenation of methanol. Ueda et al. performed the reaction of methanol with acetone over various transition metal catalysts supported on MgO using an acetone/methanol molar ratio of 1/10. The best performances are obtained with a catalyst containing 3.1 wt% of Fe. The main products are methyl vinyl ketone, methyl ethyl ketone, and 2-propanol. The yields are 7.1, 2.8, and 2.8 mol%, respectively, based on the charged acetone at the conversion of 20.1% selec-tivities are 34.8, 13.9, and 13.9 mol%, respectively, based on acetone. The yield of methyl vinyl ketone is much lower than that achieved in the reaction with HCHO. Unfortunately, there is no information about the reaction of methanol that exists in the feed ten times greater than acetone. It is considered that methyl ethyl ketone and 2-propanol are formed by hydrogenation of methyl vinyl ketone and acetone, respectively, with methanol. 

Catalytic hydrogenation is commonly used for the reduction of alkenes, alkynes, aromatic hydrocarbons, and aromatic heterocycles, carbonyl derivatives, nitriles, and nitro compounds. The reaction with alkenes proceeds on the surface of a heterogeneous metal catalyst, via cleavage of diatomic hydrogen and adsorption... 

For the preparation of coatings of phthalocyanines on SiOa or Ti02 using method D two routes were used (Fig. 6-3) route a - after adsorption of metal carbonyls at T (40-60°C) their decomposition to metal at T2 (130-320°C) and subsequent reaction with the nitrile at T3 (200-350°C) route b - direct reaction of the adsorbed metal carbonyl at T4 (180-250°C with the nitrile) [96]. The loading of polymeric phthalocyanines 31 on quartz particles of 2 wt.% was calculated from the amount of metal carbonyl employed and by parallel experiments on the reaction of phthalonitrile with Co2(CO)g. 

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