Hydroformylation conditions

The results obtained are reported in Table 5. Under the hydroformylation conditions, 1,3-butadiene is converted... 

The hypothesis that the cobalt carbonyl radicals are the carriers of catalytic activity was disproved by a high pressure photochemistry experiment /32/, in which the Co(CO), radical was prepared under hydroformylation conditions by photolysis of dicobalt octacarbonyl in hydrocarbon solvents. The catalytic reaction was not enhanced by the irradiation, as would be expected if the radicals were the active catalyst. On the contrary, the Co(C0)4 radicals were found to inhibit the hydroformylation. They initiate the decomposition of the real active catalyst, HCo(C0)4, in a radical chain process /32, 33/. 

The stability of phosphine-substituted Co clusters derived from Co4(CO)10(/r4-PPh)2 was examined under hydroformylation conditions using cylindrical internal reflectance (CIR) spectroscopy.148 [(CO)4Fe(//-PtBu2)Rh(CO)L], PPN[(CO)3CoO/-P(CMe3)2)Rh(CO)(HP(CMe3)2)], and... 

Chiral thioether-phosphite ligands (125) derived from 1,2-O-isopropylidenexylofuranose have been synthesized. Reaction of these chiral ligands with [Rh(cod)2]BF4 yielded [Rh(cod)(125)]BF4. These ligands were tested in the Rh-catalyzed hydroformylation of styrene. The hydroformylation results (ee values were insignificant) are discussed according to the solution structure of the species formed under hydroformylation conditions. HP NMR studies show that only the phosphite is coordinated during the catalytic reaction.390... 

Equation 2.5. Formation of propyldiphenylphosphine under hydroformylation conditions... 

Such compounds may be contacted with partially deactivated hydroformylation catalyst under non-hydroformylation conditions to effect disruption of the phosphido bridges of a rhodium cluster (Equation 2.12). After the treatment period, the catalyst solution is again suitable for hydroformylation. 

The existence of two different rhodium species co-existing on the silica support can be used as an advantage by controlling their relative amount. Under standard hydroformylation conditions, the cationic species and the neutral hydride complex are both present in significant amounts. Hence hydroformylation and hydrogenation will both proceed under a CO/H2 atmosphere. Indeed a clean one-pot reaction of 1-octene to 1-nonanol was performed, using the supported catalyst for a hydroformylation-hydrogenation cascade reaction. 98 % of the 1-octene was converted in the... 

The simplest a,/3-unsaturated aldehyde, acrolein, gives nearly quantitative yields of the hydrogenation product propionaldehyde under hydroformylation conditions. Most of the research has been conducted on acetal or acetate derivatives. 

Saturated ketones and aldehydes have been reduced to alcohols using Co2(CO)8-phosphine (P) mixtures at high H2 pressures, probably via the coordinatively unsaturated species HCo(CO)2P (187). A reassessment of experimental data on hydrogenation of aromatics (A) catalyzed by Co2(CO)8 under hydroformylation conditions has led to the suggestion that free radicals rather than organocobalt complexes are involved (188), e.g.,... 

A number of catalysts are known to effect homogeneous hydrogenation of aromatic hydrocarbons, e.g., some oxidized rhodium complexes (/, p. 238), some rhodium 7r-complexes with phenyl carboxylates (/, p. 283), some Ziegler systems (/, p. 363), and Co2(CO)8 (/, p. 173). However, the catalysts in the first three systems are not well characterized, and the carbonyl systems require fairly severe hydroformylation conditions, although they are reasonably selective, possibly via radical pathways (Section II, C). 

The first report of rhodium catalysts for aldehyde reduction came from Marko who reported the use of RhCl3 3H20 under hydroformylation conditions [9]. It was suggested that the active species were rhodium carbonyls, and the catalyst system was successfully utilized in the hydrogenation of ethanal, propanal, and benzalde-... 

The first catalyst used in hydroformylation was cobalt. Under hydroformylation conditions at high pressure of carbon monoxide and hydrogen, a hydrido-cobalt-tetracarbonyl complex (HCo(CO)4) is formed from precursors like cobalt acetate (Fig. 4). This complex is commonly accepted as the catalytic active species in the cobalt-catalyzed hydroformylation entering the reaction cycle according to Heck and Breslow (1960) (Fig. 5) [20-23]. 

To investigate whether a relationship exists between the solution structures of the hydridorhodium diphosphite species [RhH(CO)2(diphosphite)] [48] and catalytic performance, van Leeuwen and co-workers extensively studied the rhodium-diphosphite complexes formed under hydroformylation conditions by high-pressure NMR (HPNMR) techniques. It is well known that these complexes have a trigonal bipyramidal (TBP) structure. Two isomeric structures of these complexes, one containing the diphosphite coordinated in a bis-equatorial (ee) fashion and one containing the diphosphite in an equatorial-axial (ea) fashion, are possible (Fig. 4). 

The characterization of the rhodium complexes formed under hydroformylation conditions by NMR techniques and in situ IR spectroscopy showed that there is a relationship between the structure of the [HRh(CO)2 (BINAPHOS)] species and their enantiodiscriminating performance. Thus, (R,S)- and (S,R)-BINAPHOS ligands show high equatorial-axial (ea) coordination preference with the phosphite moiety in the axial position. Meanwhile, the characterization of the (R,R)- and (S,S)-BINAPHOS ligands suggests that there is either a structural deviation of the monohydride complexes from an ideal TBP structure or an equilibrium between isomers [20,34],... 

Abstract Aldehydes obtained from olefins under hydroformylation conditions can be converted to more complex reaction products in one-pot reaction sequences. These involve heterofunctionalization of aldehydes to form acetals, aminals, imines and enamines, including reduction products of the latter in an overall hydroaminomethylation. Furthermore, numerous conversions of oxo aldehydes with additional C.C-bond formation are conceivable such as aldol reactions, allylations, carbonyl olefinations, ene reactions and electrophilic aromatic substitutions, including Fischer indole syntheses. 

Tandem procedures under hydroformylation conditions cannot only make use of the intrinsic reactivity of the aldehyde carbonyl group and its acidic a-position but they also include conversions of the metal alkyl and metal acyl systems which are intermediates in the catalytic cycle of hydroformylation. Metal alkyls can undergo -elimination leading to olefin isomerization, or couplings, respectively, insertion of unsaturated units enlarging the carbon skeleton. Similarly, metal acyls can be trapped by addition of nucleophiles or undergo insertion of unsaturated units to form synthetically useful ketones (Scheme 1). 

Imines and enamines under hydroformylation conditions can also be reduced to give saturated amines. With or without additional reduction, these conversions can be used in synthesis of various types of heterocycles. 

Di- or tetrahydropyrans with vinyl side chains obtainable by diastereo-selective ring closing metathesis or by addition of vinylmagnesium chloride to appropriately functionalized tetrahydropyranones are converted to spirocyclic hemiacetals under hydroformylation conditions (Scheme 4) [33]. Oxidation yields the corresponding lactones. 

Similar to the formation of AT.A/ -acetals under hydroformylation conditions attack of the carbonyl carbon by primary or secondary amines can lead to imines and enamines, respectively (Scheme 11). 

A similar formation of indoles has been achieved starting from o-nitro-styrenes. Under hydroformylation conditions, the nitro group is reduced to the amino group, which condenses with the in situ generated aldehyde [48].This approach is comparable with the indole syntheses of Reis-sert [49], Batcho and Leimgruber [50], and Sugasawa [51]. 

In a similar manner, polymers with unsaturated chains or side chains can be converted to polyamines [66-69]. Conjugated diolefins usually undergo hydroformylation with low selectivities [70]. Mostly hydrogenation of at least one double bond occurs and mixtures of various saturated and unsaturated amines and diamines are obtained [71]. Similar to alkenes also alkynes may serve as unsaturated compounds in hydro aminomethylation reaction sequences. Although synthetically attractive, only a few investigations towards hydroformylation and hydroaminomethylation of alkynes in the presence of N-nuclcophilcs are known. Usually a preferred transformation to furanonic derivatives is observed under hydroformylation conditions [27]. 

In a similar fashion, allylboronates can be used as allylation reagents under hydroformylation conditions. Thus condensed 1,5-oxazadecalin systems are achieved via tandem hydroformylation/allylboration/hydroformylation sequences starting from an N-allyl-y-amidoallylboronate (Scheme 23) [77,78]. The aldehyde obtained from a regioselective hydroformylation undergoes diastereoselective intramolecular allylboration to give an intermediate al-lylic alcohol derivative. The reaction does not stop at this stage, since this... 

Aldehydes and imines derived from them can undergo electrophilic attack of activated aromatic systems under harsh hydroformylation conditions (Scheme 25). 

If the hydroformylation of olefins is conducted in the presence of aromatic hydrazines and Bronsted or Lewis acids indoles can be obtained directly in one pot [91-93,95]. Hydroformylation of the olefin gives an intermediate aldehyde, which is trapped immediately by the present aromatic hydrazine as an aromatic hydrazones similar to the formation of imines under hydroformylation conditions. Under acid mediation these aromatic hydrazones undergo a Fischer indolization, consisting of a [3,3]-sigmatropic rearrangement followed by a cyclization and elimination of ammonia (Scheme 38). 

Schmidt AM, Eilbracht P (2004) Multiple Carbon-Carbon Bond Formations under Hydroformylation Conditions. In Beller M, Bolm C (eds) Transition Metals for Organic Synthesis Building Blocks and Fine Chemicals. Wiley, Weinheim, p 87... 

Thermal decomposition of RhH(CO)(PPh3)3, the well known hydroformylation catalyst, in the absence of H2 and CO leads to a stable cluster shown in Figure 2.36 containing p2-PPh2 fragments [31], Under hydroformylation conditions also other products are found such as benzaldehyde, benzene, and diphenylpropylphosphine. 

The tetranuclear and trinuclear clusters will only be observed at low pressures [8], but all other species are very common under hydroformylation conditions. Complex 4 is an ionic complex that is formed in polar solvents [9] and even hexa-solvated, divalent cobalt species may form as the cation. Under practical conditions both the dimers and the hydrides are observed, thus depending on the hydrogen pressure there will be more or less of the hydride present. 

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