Alkenes formylation

The hydroformylation of ( >3-methylpent-2-ene and (Z)-3-methyIpent-2-ene in the presence of [RhH(CO)PPh3)a] reveal that there is a cis addition of hydrogen and formyl group in the reaction. Deuterioformylation also establishes that the stereospecificity of the reaction is very high. Asymmetric hydroformylation of aliphatic alkenes can also be achieved using a catalyst system prepared from [RhH(CO)-(PPha)3] and (-)-diop (49). In the case of prochiral alkene formylation the predominating enantiomer of the aldehyde is always formed by addition of CO and H to the same prochiral side of the alkene (Scheme 28). ... 

Oxo or Hydroformylation and Hydroesterification. Reactions of alkenes with hydrogen and formyl groups are cataly2ed by HCo(CO)4... 

VILSMEIER - HAACK - VIEHE Reagent Formylation of aremalics, alkenes, activated H compounds by MeaN -CHCI Cl (Vilsmeier-... 

Other functional groups provide sufficient stabilization of radicals to permit successful chain additions to alkenes. Acyl radicals are formed by abstraction of the formyl hydrogen from aldehydes. As indicated in Table 12.7, the resulting acyl radicals are... 

With respect to aromatic substrates, the Vilsmeier formylation reaction works well with electron-rich derivatives like phenols, aromatic amines and aromatic heterocycles like furans, pyrroles and indoles. However various alkenes are also formylated under Vilsmeier conditions. For example the substituted hexatriene 6 is converted to the terminal hexatrienyl aldehyde 7 in 70% yield ... 

Although limited to electron-rich aromatic compounds and alkenes, the Vilsmeier reaction is an important formylation method. When yV,A-dimethylformamide is used in excess, the use of an additional solvent is not necessary. In other cases toluene, dichlorobenzene or a chlorinated aliphatic hydrocarbon is used as solvent. ... 

Formylation of alkenes can be accomplished with N-disubstituted formamides and POCl3. ° This is an aliphatic Vilsmeier reaction (see 11-15). Vilsmeier formylation can also be performed on the ot position of acetals and ketals, so that hydrolysis of the products gives keto aldehydes or dialdehydes ... 

The enantioselectivity of the BINOL-Ti(IV)-catalyzed reactions can be interpreted in terms of several fundamental structural principles.42 The aldehyde is coordinated to Ti through an apical position and there is also a 0-HC=0 hydrogen bond involving the formyl group. The most sterically favored approach of the alkene toward the complexed aldehyde then leads to the observed product. Figure 10.2 shows a representation of the complexed aldehyde and the TS structure for the reaction. 

Fig. 12.4. Successive models of the transition state for Sharpless epoxidation. (a) the hexacoordinate Ti core with uncoordinated alkene (b) Ti with methylhydroperoxide, allyl alcohol, and ethanediol as ligands (c) monomeric catalytic center incorporating t-butylhydroperoxide as oxidant (d) monomeric catalytic center with formyl groups added (e) dimeric transition state with chiral tartrate model (E = CH = O). Reproduced from J. Am. Chem. Soc., 117, 11327 (1995), by permission of the American Chemical Society. 

The desired product in the hydroformylation of allyl alcohol is 4-hydroxybutanal. As with other alkenes, hydro formylation gives both a linear and a branched isomer (Equation 2.1). 

Arylphosphines in rhodium catalyzed hydroformylation reactions exchange an aryl group for an alkyl, principally linear alkyl, corresponding to the alkene being hydro-formylated to give an alkyldiarylphosphine [22](see Equation 2.5). 

Alkene isomerization has both positive and negative aspects. The positive aspect is where isomerization is needed prior to, for example, hydro formylation to give the desired product. The negative aspect of alkene isomerization is similar to that described in Section 2.6.2.1 on hydrogenation. The byproduct must be separated from both catalyst and product, and recycle opportunities may be limited. Not only is isomerization a direct efficiency loss, but when the isomerised alkene is purged, desired reactants will likely also be lost. 

Figure 6.1 The fluorous biphase concept illustrated for the hydro formylation of an alkene (substrate) to an...

The base-catalysed addition of thiols to Jt-electron-deficient alkenes is an important aspect of synthetic organic chemistry. Particular use of Triton-B, in place of inorganic bases, has been made in the reaction of both aryl and alkyl thiols with 1-acyloxy-l-cyanoethene, which behaves as a formyl anion equivalent in the reaction [1], Tetra-n-butylammonium and benzyltriethylammonium fluoride also catalyse the Michael-type addition of thiols to a,P-unsaturated carbonyl compounds [2], The reaction is usually conducted under homogeneous conditions in telrahydrofuran, 1,2-dimethoxyethane, acetone, or acetonitrile, to produce the thioethers in almost quantitative yields (Table 4.22). Use has also been made of polymer-supported qua-... 

Even if hydrides of transition metals play an important role as intermediates in catalytic processes such as hydrogenation and hydro-formylation of alkenes and the Fischer-Tropsch reaction,71 in order to follow with the bioinorganic subject, we refer to the interconversion process ... 

In sharp contrast to the unique pattern for the incorporation of carbon monoxide into the 1,6-diyne 63, aldehyde 77 was obtained as the sole product in the rhodium-catalyzed reaction of 1,6-enyne 76 with a molar equivalent of Me2PhSiH under CO (Scheme 6.15, mode 1) [22]. This result can be explained by the stepwise insertion of the acetylenic and vinylic moieties into the Rh-Si bond, the formyl group being generated by the reductive elimination to afford 77. The fact that a formyl group can be introduced to the ole-finic moiety of 76 under mild conditions should be stressed, since enoxysilanes are isolated in the rhodium-catalyzed silylformylation of simple alkenes under forcing conditions. The 1,6-enyne 76 is used as a typical model for Pauson-Khand reactions (Scheme 6.15, mode 2) [23], whereas formation of the corresponding product was completely suppressed in the presence of a hydrosilane. The selective formation of 79 in the absence of CO (Scheme 6.15, mode 3) supports the stepwise insertion of the acetylenic and olefmic moieties in the same molecules into the Rh-Si bond. 

Other ligands chosen by a similar strategy were also reported (172,174). They have been used to retain rhodium complexes in ionic liquids for alkene hydro-formylation. 

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