Aldehydes stoichiometric allylation

Alkylation of aldehydes.1 Sml2 (stoichiometric amount) effects alkylation of aliphatic aldehydes with allylic and benzylic halides. The reaction is not applicable to aromatic aldehydes, which are rapidly converted topinacols in the presenceol SmI2. Examples ... 

While the chiral aldehydes or allyl nucleophiles are based on stoichiometric amounts for the control of diastereoselectivity [74, 77], it has been found that catalytic amounts of titanium complexes derived from BINOL can mediate the enantioselective addition of allyl stannanes to aldehydes, giving the homoallyl alcohols high enantioselectivity. Mikami reported that the BINOL-Ti complexes prepared in situ in the presence of 4A molecular sieves (MS) catalyze the carbonyl addition reaction of allyl silanes or stannanes to afford the syn product in high enantiomeric excess [78] (Scheme 14.21). 

Chiral Lewis-basic catalysts, in particular phosphoratnides (1 and 2),2-13c. 16.46,47 pyridine iV,iV-bisoxides (3 and and pyridine iV-monoxides (5, 6 and 7,8),3 exhibit very high enantioselectivities for the allylation of aromatic, heteroaromatic, and cinnamyl-type aldehydes with allyl, ( )- and (Z)-crotyl, and prenyl trichlorosilanes. Chiral formamides, pyridine-oxazolines, urea derivatives, and sulfoxides are generally less enantioselective and effective only in stoichiometric quantities. The reaction is much less efficient with aliphatic aldehydes, which require stoichiometric conditions (vide infra). However, a, -unsaturated aldehydes do react readily and give 1,2-addition products. 

The first report on the conceptually new asymmetric catalysis described that both a stoichiometric amount of SiCU and a catalytic amount of chiral phosphoramide (107) promote highly enantioselective allylation and propargylation of aromatic aldehydes with allyl- and allenyl-tributylstannane, respectively [41], The allylation does not proceed without (107). In the proposed mechanism, SiCU, a weak achiral Lewis acid, accepts the Lewis base (107) to form a strong chiral Lewis acid by polarization of the Si-Cl bonds. The active Lewis acid promotes the asymmetric reaction to give trichlorosilylated adducts with regeneration of (107) (Scheme 9.74). 

Metzner and co-workers reported a one-pot epoxidation reaction in which a chiral sulfide, an allyl halide, and an aromatic aldehyde were allowed to react to give a trons-vinylepoxide (Scheme 9.16c) [77]. This is an efficient approach, as the sulfonium salt is formed in situ and deprotonated to afford the corresponding ylide, and then reacts with the aldehyde. The sulfide was still required in stoichiometric amounts, however, as the catalytic process was too slow for synthetic purposes. The yields were good and the transxis ratios were high when Ri H, but the enantioselectivities were lower than with the sulfur ylides discussed above. 

Later, Araki et al. found that the allylation of aldehydes and ketones can be carried out by using catalytic amounts of indium(III) chloride in combination with aluminum or zinc metal.109 This reaction was typically performed in a THF-water (5 2) mixture at room temperature, although the conversion was much slower compared to the same reaction mediated by use of a stoichiometric amount of indium and it required days to complete. When the reaction was carried out in anhydrous THF alone, the yield dropped considerably and side-reactions such as reduction to alcohol increased. The combinations of Al-InCL or Zn-InCl3 gave comparable results. 

Intermolecular allylation of aldehydes with 1 -trialkylsilyl-1,3-dienes 22 in the presence of a stoichiometric amount of triethylsilane and a catalytic amount of Ni(cod)2 and PPI13 shows novel regio- and stereoselectivity (Scheme 6) [20-22], When a toluene solution of a 1-silyl-1,3-diene and an aldehyde is refluxed in the presence of trialkylsilane under the catalysis of Ni(cod)2 and PPh3, ( )-allylsilane (E)-23 is obtained exclusively. On the other hand, when the reaction is carried out in THF upon heating at 50 °C as... 

If the alkenes and acetylenes that are subjected to the reaction mediated by 1 have a leaving group at an appropriate position, as already described in Eq. 9.16, the resulting titanacycles undergo an elimination (path A) as shown in Eq. 9.58 [36], As the resulting vinyltitaniums can be trapped by electrophiles such as aldehydes, this reaction can be viewed as an alternative to stoichiometric metallo-ene reactions via allylic lithium, magnesium, or zinc complexes (path B). Preparations of optically active N-heterocycles [103], which enabled the synthesis of (—)-a-kainic acid (Eq. 9.59) [104,105], of cross-conjugated trienes useful for the diene-transmissive Diels—Alder reaction [106], and of exocyclic bis(allene)s and cyclobutene derivatives [107] have all been reported based on this method. 

Carbanions, generated by the reaction of benzylsilanes with tetra-n-butylammo-nium fluoride react with non-enolizable aldehydes to produce the alcohol [67], When a stoichiometric amount of the ammonium fluoride is used, the methylarene corresponding to the benzylsilane is frequently a by-product and arises from formation of the hydrogen difluoride salt during the reaction. When only catalytic amounts of the ammonium fluoride initiate the reaction, the formation of the methylarene is suppressed. In a similar type of reaction (although the mechanism is not known) between aldehydes and ketones, allyl bromide, and tin in the presence of trimethylsilyl chloride the yield of the but-l-en-4-ol is raised significantly by the addition of tetra-n-butylammonium bromide, particularly in the reactions with... 

Reduction of conjugated carbonyl compounds using stoichiometric amounts of the ammonium salt shows little advantage over the sodium salt in acidic methanol [11] with both reagents producing allylic alcohols (58-88% for acyclic compounds and 15-64% for cyclic compounds) by selective 1,2-reduction of the conjugated systems. Aldehydes, ketones and conjugated enones are also reduced by tetra-n-butylammonium cyanoborohydride in HMPA [11, 12], whereas haloalkanes and alkanesulphonic esters are cleaved reductively under similar conditions [13]. 

The Barhier-type reaction of aldehydes and ketones with allyl halides (485) in the presence of Sml2, leading to homoallyl alcohols (486), has received recent interest as a one-step alternative to the Grignard reaction. However, the reactions require the use of stoichiometric amounts of the reducing Sm(III) species. Recently, the electroreductive Barhier-type allylation of carbonyl compounds in an SmH-mediated reaction has been developed [569]. The electrolysis of (485) is carried out in a DMF-SmCl3-(Mg/Ni) system in an undivided cell to give the adduct (486) in 50 85% yields (Scheme 168) [569]. Electrosynthesis of y-butyrolactones has been achieved by the reductive coupling of ethyl 3-chloropropionate with carbonyl compounds in the presence of a catalytic amount of SmCfi [570]. 

In addition, Iseki et al. reported a highly enantioselective allylation reaction with ahphatic and unconjugated aldehydes. They used chiral DMF derivatives and observed a dramatic increase in the yield and enantioselectivity of the reaction, when a stoichiometric amount of HMPA was employed [57, 58]. 

Abstract The purpose of this chapter is to present a survey of the organometallic chemistry and catalysis of rhodium and iridium related to the oxidation of organic substrates that has been developed over the last 5 years, placing special emphasis on reactions or processes involving environmentally friendly oxidants. Iridium-based catalysts appear to be promising candidates for the oxidation of alcohols to aldehydes/ketones as products or as intermediates for heterocyclic compounds or domino reactions. Rhodium complexes seem to be more appropriate for the oxygenation of alkenes. In addition to catalytic allylic and benzylic oxidation of alkenes, recent advances in vinylic oxygenations have been focused on stoichiometric reactions. This review offers an overview of these reactions... 

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