Enolates diethylaluminum

It must be noted that the cyclic model fails to account for the role of the additional alkyllithium and diethylaluminum that are required in precise amounts to achieve high selectivity. A simple model that recognizes a possible role for the additional reagents suggests the intermediacy of an extended, noncyclic transition state G with the aldchydic oxygen coordinated to some undefined Lewis acidic species derived from the additional components of the reaction mixture26,44. Aggregates composed of enolate, alkyllithium and dialkylaluminum species are also possible. 

Conducting the aldol reaction at temperatures below —78 "C increases the diastereoselectivity, but at the cost of reduced yields45. Transmetalation of the lithium enolate 2 a by treatment with diethylaluminum chloride generated an enolate species that provided high yields of aldol products, however, the diastereoselectivity was as low as that of the lithium species45. Pre treatment of the lithium enolate 2a with tin(II) chloride, zinc(II) chloride, or boron trifluoridc suppressed the aldol reaction and the starting iron-acyl complex was recovered. 

Reaction of the lithium enolate 2 with prochiral aldehydes at low temperature proceeds with little selectivity, producing all four possible diastereomers 3, 4, 5, and 6 in similar amounts50. Transmetalation of the lithium enolate by treatment with three equivalents of diethylaluminum chloride or with one equivalent of copper cyanide generates the corresponding cthylaluminum and copper enolates which react at — 100°C with prochiral aldehydes to produce selectively diastereomers 1 and 2, respectively50. The reactivity of tin enolates of iron- propanoyl complexes has not been described. 

In contrast, transmetalation of the lithium enolate at —40 C by treatment with one equivalent of copper cyanide generated a species 10b (M = Cu ) that reacted with acetaldehyde to selectively provide a 25 75 mixture of diastereomers 11 and 12 (R = CH3) which are separable by chromatography on alumina. Other diastereomers were not observed. Similar transmetalation of 10a (M = Li0) with excess diethylaluminum chloride, followed by reaction with acetaldehyde, produced a mixture of the same two diastereomers, but with a reversed ratio (80 20). Similar results were obtained upon aldol additions to other aldehydes (see the following table)49. 

Transmetalation of 19 by treatment with two equivalents of diethylaluminum chloride generates the aluminum enolate species 23. The latter reacts with acetaldehyde to produce the stable aluminum aldolates 24 which do not undergo the Peterson elimination23. A protic quench then provides the a-silylated aldol adducts of tentative structures (2 R)-25 and (2 V)-25 with little diastereoselectivity. Other diastereomers are not observed. 

Scheme 7.5 gives some examples of the Reformatsky reaction. Zinc enolates prepared from a-haloketones can be used as nucleophiles in mixed aldol condensations (see Section 2.1.3). Entry 7 is an example. This type of reaction can be conducted in the presence of the Lewis acid diethylaluminum chloride, in which case addition occurs at -20° C.171... 

Twofold Michael additions have been utilized by the groups of Spitzner [2] and Hagiwara [3] to construct substituted bicyclo[2.2.2]octane frameworks. In Hagiwara s approach towards valeriananoid A (2-6) [4], treatment of trimethylsily-enol ether 2-2, prepared from the corresponding oxophorone 2-1, and methyl acrylate (2-3) with diethylaluminum chloride at room temperature (r.t.) afforded the bicyclic compound 2-4 (Scheme 2.2). Its subsequent acetalization allowed the selective protection of the less-hindered ketone moiety to provide 2-5, which could be further transformed into valeriananoid A (2-6). 

The ene reaction is strongly catalyzed by Lewis acids such as aluminum chloride and diethylaluminum chloride204 Coordination by the aluminum at the carbonyl group increases the electrophihcity of the conjugated system and allows reaction to occur below room temperature, as illustrated in Entry 6. Intramolecular ene reactions can be carried out under either thermal (Entry 3) or catalyzed (Entry 7) conditions 205 Formaldehyde in acidic solution can form allylic alcohols, as in entry 1. Other carbonyl ene reactions are carried out with Lewis acid catalysts. Aromatic aldehydes and acrolein undergo the ene reaction with activated alkenes such as enol ethers in the presence of Yb(fod)3 206 Sc(03SCF3)3 has also been used to catalyze ene reactions.207... 

Treatment of lithium enolate species, such as 7, with a variety of metal halide species produces enolates with different reactivities in particular, diethylaluminum(IH) and copper(I) species have been found to profoundly alter stereodifferentiation in reactions of iron acyl enolates (see Section D.1.3.4.2.5.1.). It has not been established whether complex formation or discrete ti ansmetalation occurs usually, a temperature increase from — 78 °C to — 42 °C is required for maximum effect, suggesting that cation exchange is responsible. In some cases, such additives exert an influence at —78 °C13, and this has been attributed to simple Lewis acid-type interactions with the substrate instead of transmetalation of the enolate species. For simplicity, when such additives are allowed to react with enolate species at temperatures of — 42 =C and above prior to the addition of other reagents, the process shall be referred to as transmetalation. 

Enolate species 6, derived from 1-oxopropyl complex 5, reacts similarly with monosubstituted epoxides. Under the influence of diethylaluminum chloride, only the diastereomers 7 and 8 were observed in the reaction mixture 7 was the major product. The use of boron trifluoride - diethyl ether complex instead of diethylaluminum chloride caused a complete loss of stereocontrol at C , producing a 50 50 mixture of diastereomers 7 and 8, but stereocontrol at C was retained as no other diastereomers were produced. The major diastereomer produced is consistent with the intermediacy of a transition state like that represented in Newman projection C which has the usual anti-E-snolate geometry and lacks the R methyl gauche interaction of structure D. 

Polymerizations ofMethacrylic Esters Initiated with Diethylaluminum Enolate... 

Reaction of ester enolates with epoxides.1 Lithium enolates of esters do not open epoxides, but the aluminum enolates do. Li to A1 exchange can be effected with diethylaluminum chloride. The less substituted O-C bond is cleaved and the syn-diastereomer predominates. Reactions of optically active epoxides proceed with high... 

Vinyl epoxides can also be ring-opened via an Sn2 sense, as exemplified in the macrocyclization of the epoxy-tethered cyclopentenone 76, which was induced to occur by treatment with lithium 2,2,6,6-tetramethylpiperidide (LTMP) followed by the mild Lewis acid diethylaluminum chloride in THF. The enolate attacked exclusively from the a-position of the... 

Stereoselective condensation with imines. The diethylaluminum enolate of 1 reacts with a wide variety of imines with high stereofacial bias, which is ascribed to a cyclic transition state in an aluminum chelate. 

Enaminones. Coupling of enol silyl ethers with oxime mesylates can be effected via a Beckmann rearrangement with diethylaluminum chloride. 

Non-Evans Aldol Reactions. Either the syn- or onri-aldol adducts may be obtained from this family of imide-derived eno-lates, depending upon the specific conditions employed for the reaction. Although the illustrated boron enolate affords the illustrated jyn-aldol adduct in high diastereoselectivity, the addition reactions between this enolate and Lewis acid-coordinated aldehydes afford different stereochemical outcomes depending on the Lewis acid employed (eq 35). Open transition states have been proposed for the Diethylaluminum Chloride mediated, anti-selective reaction. These anfi-aldol reactions have been used in kinetic resolutions of 2-phenylthio aldehydes. ... 

Coixjugate Addition Reactions. a,3-Unsaturated N-acyloxazolidinones have been implemented as Michael acceptors, inducing chirality in the same sense as in enolate alkylation reactions. Chiral a,3-unsaturated imides undergo 1,4-addition when treated with diethylaluminum chloride (eq 55). Photochemical initiation is required for the analogous reaction with Dimethylaluminum Chloride. ... 

Lewis acid catalysis of the vinylcyclopropane rearrangement has been reported for vinylcy-clopropane 3, a key intermediate in the synthesis of the plant hormone antheridogen-An. Most recently, a report has appeared describing a highly stereoselective, diethylaluminum chloride promoted rearrangement of vinylcyclopropanes 5 to cyclopentenes 6. The cyclopen tenes appear to be formed directly, in some cases as a consequence of the rhodium-promoted cyclopropanation of enol ethers (see Section 2.4.3.1.3.). ... 

Nozaki and coworkers reported that diethylaluminum 2,2,6,6-tetramethylpiperidine (DATMP) is capable of producing diethylaluminum enolates by deprotonation of ketones or esters at -23°C in THF (Scheme 6.23) [43]. Unlike the instabih-ty of the corresponding lithium enolate, the aldol reaction of the aluminum enolate of t-butyl acetate prevails over the alkoxy ehmination that produces the ketene species, even at -23 °C. 

Aluminum enolates can be obtained also by transmetallation of lithium enolates (Scheme 31 ). 3 Diethylaluminum enolates can be produced regiospecifically through reaction of diethylaluminum chloride and zinc dust with a-bromo ketones and esters (Scheme 32). Obviously zinc is involved in this reaction, but the mild conditions are in sharp contrast to the Refoimatsky reaction and support the existence of an aluminum enolate in this process. The same type of enolate can be obtained from r-butyi acetates and diethylaluminum 2,2,6,6-tetramethylpiperidide (DATMP), which is generated in situ from diethylaluminum chloride and LITMP (Scheme 33). ... 

A similar method for the formation of enolates derived from esters and ketones uses diethylaluminum 2,2,6,6-tetramethylpiperidide (DATMP), as shown in Scheme 58. ... 

Reaction of an alkenyloxydiethylalane with an imine has been reported by Iwasaki and Shibasaki (Scheme 59). The diethylaluminum enolate derived from S-/-butyl alkanethioate, upon reaction with imine (134), furnishes P-lactams (135) and (136) in an anti selective manner. 

Regiosp>ecific synthesis of enol silyl ethers can also be achieved from enones either by reductive silylation or by 1,4-addition of the conjugated system. Thus, Li/NH reduction of the decalone (27) and silylation give the enol silyl ether (28). Similarly, addition of lithium dimethylcuprate to cyclohexenone followed by silylation gives the enol silyl ether (29). Trimethylsilyl cyanide (30) normally adds 1,2 to conjugated ketones (e.g. carvone, 31). However, in the presence of trialkylaluminum, 1,4-addition bdces place to give the enol silyl ether (32 Scheme 9). The same overall transformation can be accomplished by diethylaluminum cyanide and trimethylchlorosilane. ... 

Aldol synthesis. A new synthesis of 3-hydroxy ketones and esters involves regiospecific conversion of an a-bromo ketone or ester into an aluminum enolate by a coupled reaction with diethylaluminum chloride and zinc activated with copper(I) bromide in THF at —20°. This enolate adds to carbonyl compounds to give, after work-up, j3-hydroxy ketones (equation I). 

It has also been shown that in the presence of 3-methylcyclo-hexenone, treatment of diethylaluminum cyanide with TBAT provides the cyanide conjugate addition product." The enolate can be captured when the reaction is run in the presence of triflic anhydride, providing the triflate. 

Harrity exploited the carbocation stabilizing ability of cobalt-alkyne complexes to promote a novel O C rearrangement reaction. Exposure of cyclic enol ether 23 to diethylaluminum chloride promotes ionization of the C-O bond to yield the stabilized carbocation and an enolate. Bond rotation followed by C-C bond formation provides cyclohexanone product 24. ... 

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