Hexamethylphosphoric triamide substitution reactions

The Heck reaction is considered to be the best method for carbon-carbon bond formation by substitution of an olefinic proton. In general, yields are good to very good. Sterically demanding substituents, however, may reduce the reactivity of the alkene. Polar solvents, such as methanol, acetonitrile, N,N-dimethylformamide or hexamethylphosphoric triamide, are often used. Reaction temperatures range from 50 to 160 °C. There are various other important palladium-catalyzed reactions known where organopalladium complexes are employed however, these reactions must not be confused with the Heck reaction. 

Dipolar aprotic solvent. This cyclic urea can serve as a substitute for the carcinogenic hexamethylphosphoric triamide (HMPT) in reactions of highly nucleophilic and basic reagents. It mimics the effect of HMPT in Wittig olefination und in selective generation of various enolates. It forms homogeneous solutions with I IIF even at -78°. ... 

RCO , an indifferent nucleophile in prohc solvents, enjoys a large rate enhancement, permitting rapid alkylation with haloalkanes in hexamethylphosphoric triamide [301, 302], When the Williamson ether synthesis is carried out in dimethyl sulfoxide [303], the yields are raised and the reaction time shortened. Displacements on unreactive haloarenes become possible [304] (conversion of bromobenzene to tert-butoxybenzene with tert-C UgO in dimethyl sulfoxide in 86% yield at room temperature). The fluoride ion, a notoriously poor nucleophile or base in protic solvents, reveals its hidden capabilities in dipolar non-HBD solvents and is a powerful nucleophile in substitution reactions on carbon [305],... 

Indeed, in diethyl ether, lithium dimethylcuprate usually reacts with the a-enone group to give a methyl-substituted bromo ketone. Addition of hexamethylphosphoric triamide (HMPT), however, slows down this reaction to such an extent that displacement of the bromo substituent takes place [698], Another remarkable example of the influence of HMPT on chemoselectivity is the reaction of an arsonium ylide, Ph3As= CH-CH=CH-Ph, with benzaldehyde in tetrahydrofuran solution, yielding either an epoxide (in THE) or an alkene (in THF/HMPT) [699],... 

A nonpolar solvent favors conformation A, whereas conformation B is favored by more polar solvents (e.g. dimethylformamide, hexamethylphosphoric triamide) because the cation is more solvated (cf. Table 9, entries 1 and 2). However, this solvent effect is absent when BujP Cu" is used as counterion. Conformation A is more favored by relatively small counterions, such as the lithium and sodium ion, as compared to the larger potassium ion, due to the higher degree of association of the former. Steric strain between ASG and ASG is minimized in conformation B. Conformations A and B lead to trans- and c -substituted cyclopropanes, respectively. A study of cyclopropane esters, -in which the stereoselectivity of the reaction of polymer-supported reagents was compared with molecules of low-molecular weight, made clear that the steric and polar microenvironment of the polymer-supported reaction is not different enough in bulk to influence the selectivity substantially. Nevertheless, a specific influence of the solid phase can be observed at low temperatures. 

Dimethyl-4,8-dioxaspiro[2.5]oct-l-ene is a synthetically useful precursor for cyclopropenones because of its stability and ready availability. The sodium derivative 1 of the cyclopropenone acetal in liquid ammonia reacted with alkyl halides giving alkyl-substituted cyclopropenone acetals 3. The lithiated cyclopropenone acetal 4 was generated by treating the cyclopropenone acetal with one equivalent of butyllithium in tetrahydrofuran. Reaction of the lithium carbanion 4 with alkyl halides proceeded cleanly in the presence of two equivalents of hexamethylphosphoric triamide (Table 1, entries 1-4). The lithium compound underwent nucleophilic addition to carbonyl compounds smoothly at — 70 C giving hydroxymethyl derivatives 5 (Table 1, entries 5-10). 

Summary Reacting 2-neopentyl substituted silacyclobutanes la,b with MeLi/HMPA (hexamethylphosphoric triamide) anionic polymerization to give polymers 3a,b plays only a minor role for product formation. Instead, the head-to-head dimers 2a,b are isolated as main products. Their formation is explained by a complex reaction mechanism, in which various carbanionic, highly reactive intermediates are discussed. Obviously, the bis-a-silyl substituted carbanions 10a,b are remarkably stable, as can be concluded from Si NMR spectroscopic investigations at low temperature and from the products formed by trapping reactions with alcohols. 

Another novel and useful method for the synthesis of pyridine derivatives was reported using lithiated butadienes [22]. 1-Lithio-1,3-butadienes 50 treated with nitriles in the presence of hexamethylphosphoric triamide (HMPA) at room temperature for 1 h gave the substituted pyridines in excellent yields (Scheme 11.20). The butadienylketimine 51 is the key intermediate of the reaction. The same pyridine formation occurred in the reaction of nitriles with the corresponding 1,4-dilithio 1,3-butadienes 35, but the existence of a different mechanism was indicated by nuclear magnetic resonance (NMR) observation of the reaction mixture. 

The prototype of this class, OP(NH2)3, is formed in the reaction of OPCI3 with liquid ammonia orwith gaseous NH3 in trichloromethane solution at low temperature. Substituted phosphoric acid triamides 0=P(NR2)3 are prepared in the reaction of phosphoras oxotrichloride with secondary amines, under heating or in the presence of acid scavengers under milder conditions the mono- and diamido chlorides can be easily obtained (equation 6). Hexamethylphosphoric acid triamide, OP(NMc2)3, an excellent aprotic organic solvent prepared from OPCI3 and dimethylamine, deserves to be mentioned here. ... 

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