Esters preferred reaction conditions

Carbamates by Aminolysis of Carbonate or Dithiocarbonate Esters Diethyl carbonate has been employed for the cydocarbamation of various amino alcohols. The reaction is catalyzed by basic substances, such as sodium methoxide, magnesium methoxide, potassium hydroxide, or sodium or potassium carbonates. Sodium methoxide in xylene [485-487], or potassium or sodium carbonate under reflux [488-493] are the preferred reaction conditions. The reaction has wide scope and synthetic utility. 

This mechanism of a -elimination reaction is supported by experimental findings with " S- and C-labeled starting materials." The Chugaev reaction is analogous to the ester pyrolysis, but allows for milder reaction conditions—i.e. it occurs at lower temperatures. It is less prone to side reactions, e.g. the formation of rearranged products, and is therefore the preferred method. 

An antipolymerization agent such as hydroquinone may be added to the reaction mixture to inhibit the polymerization of the maleate or fumarate compound under the reaction conditions. This reaction is preferably carried out at a temperature within the range of 20°C to 150°C. This reaction is preferably carried out at atmospheric pressure. Reaction time of 16 to 24 hours have bean specified for this reaction by J.T. Cassaday. The reaction is preferably carried out in a solvent such as the low molecular weight aliphatic monohydric alcohols, ketones, aliphatic esters, aromatic hydrocarbons or trialkyl phosphates. 

A. Synthetic Methods.—There have been no strikingly new approaches to the general problem of phosphorylation, but several ingenious methods of preparing suitable active esters under mild conditions have been reported. Typical of these is the reactive intermediate (1) formed from reaction of a mono- or di-ester of phosphoric acid with (2), itself produced by reaction of triphenylphosphine with bis(2-pyridyl) disulphide (preferably in the presence of mercuric ion as scavenger for the 2-mercaptopyridine liberated). 

Unlike the case of the Ni-catalyzed reaction, which afforded the branched thioester (Eq. 7.1), the PdCl2(PPh3)3/SnCl2-catalyzed reaction with 1-alkyne and 1-alkene predominantly provided terminal thioester 6 in up to 61% yield in preference to 7. In 1983, a similar hydrothiocarboxylation of an alkene was also documented by using a Pd(OAc)2/P( -Pr)3 catalyst system with t-BuSH to form 8 in up to 79% yield (Eq. 7.6) [16]. It was mentioned in the patent that the Pt-complex also possessed catalyhc activity for the transformation, although the yield of product was unsatisfactory. In 1984, the hydrothiocarboxylation of a 1,3-diene catalyzed by Co2(CO)g in pyridine was also reported in a patent [17]. In 1986, Alper et al. reported that a similar transformation to the one shown in Eq. (7.3) can be realized under much milder reaction conditions in the presence of a 1,3-diene [18], and the carboxylic ester 10 was produced using an aqueous alcohol as solvent (Eq. 7.7) [19]. 

Methyl esters are always the preferred substrates, conversions being lower with, for example, ethyl esters. Functional groups such as nitro, methoxy, alkenyl and pyridyl are compatible with the reaction conditions. Diesters can only be effective if bis-transesterification is desired, when an excess of the alcohol (e.g., 3-5 equiv) is necessary. Methyl acrylate tends to polymerize under the reaction conditions, but the use of an excess of the ester (3-5 equiv) and lower temperatures (-10°C) allows efficient isolation of the required ester. 

Some studies seeking preferred conditions for this reaction have been made. Optimum yields are obtained when the amount of water present is appreciable, and it was noted that the rate of hydrogen evolution increases with increasing water content. A 75% formic acid system appears generally preferred. Under the reaction conditions examined by the submitters, olefins, ketones, esters, amides, and acids are inert, but nitro compounds are reduced to the formamide derivative. 

The 1,4-conjugate addition of ester enolates to a, 3-enones was first reported by Kohler in 1910,138a c as an anomalous Reformatsky reaction, but chemoselectivity was dependent on the structure of the a,(3-enone and restricted to bromozinc enolates obtained from either a-bromoisobutyrate or bromomalonate esters (Scheme 66).138d,e Further evaluation, with lithio ester enolates and lithio amide enolate additions, has resulted in identification of four factors that affect the chemoselectivity and diastereoselectivity of additions to a, 3-enones.139 These factors are (a) enolate geometry, (b) acceptor geometry, (c) steric bulk of the -substituent on the acceptor enone and (d) reaction conditions. In general, under kinetic reaction conditions (-78 °C), ( )-ester enolates afford preferential 1,2-addition products while (Z)-ester enolates afford substantial amounts of 1,4-addition products however, 1,2 to 1,4 equilibration occurs at 25 C in the presence of HMPA. The stereostructure of the 1,4-adducts is dependent on the initial enolate structure for example, with ( )-enones, (Z)-ester enolates afford anti adducts, while (E)-ester enolates afford syn adducts (Scheme 54). In contrast, amide enolates show a modest preference for anti diastereomer formation. 

Where possible, it is usually preferable to have the activated species (e.g., the active ester) in solution and the substrate (e.g., the amine component) on the solid phase. If the case requires an inverted situation, as for the synthesis of a thiazolidinone library (see Fig. 13),41 identification of the best reaction conditions may be more challenging, considering the relative scarcity of literature examples. 

Applying this technique to a series of four substrates, the kinetic data of Table 15 were obtained. Also included are data from homogeneous solution studies on the radical anion of 1,1-diphenyl-ethylene. For the two esters, radical anion coupling seems to be the preferred reaction mode under these conditions, whereas both mechanisms operate for the two nitriles and 1,1-diphenylethylene, k2 being 10-100 times larger than k 2 m these cases. 

As mentioned earlier, palladium, rhodium, and platinum catalysts lead to superior regioselectivities because they work under milder reaction conditions (20-80 °C, 0.1-1 MPa CO) [11], e.g., bimetallic catalysts based on tin(II) chloride and either platinum or palladium complexes afford linear esters in up to 98 % selectivity [12]. In addition, catalyst systems with preference for branched isomers are known. A recent example employed palladium acetate immobilized on montmorillonite in the presence of triphenylphosphine and an acid promoter for the hydroesterification of aryl olefins (eq. (3)). The reaction is totally regiospecific for the branched isomer of aromatic olefins, while aliphatic olefins afford branched chain esters only regioselectively with n/i = 1 3 [13]. 

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