Nucleophilic reactions with apparently

Nucleophilic reactions with apparently unreactive compounds s. 13, 618 Sec. from prim, amines and halides Hal NHR... 

Nevertheless, the use of relative reactivities to characterize carbenic philicity is restrictive the apparent philicity is related to the alkenes selected for the relative reactivity measurements. What if the set of alkenes were expanded by the addition of an even more electron-deficient alkene Such a test was applied in 1987 [65], using a-chloroacrylonitrile, 26, which is more 7t-electron deficient than acrylonitrile, 27. We found that PhCF or PhCCl added 15 or 13 times, respectively, more rapidly to 26 than to 27. In preferring the more electron-deficient olefin, the carbenes exhibited nucleophilic character. However, because they also behave as electrophiles toward other alkenes (Table 4), they must in reality be ambiphiles. In fact, we now realize that all carbenes have the potential for nucleophilic reactions with olefins the crucial factor is whether the carbene s filled a orbital (HOMO)/alkene vacant Ji orbital (LUMO) interaction is stronger than the carbene s vacant p orbital (LUMO)/aIkene filled k orbital (HOMO) interaction in the transition state of the addition reaction. [63]... 

In Chapter 5 (Section 5.5.3), it was apparent that thiols are similar to alcohols, at least in terms of nomenclature and structure. Alcohols react with aldehydes and ketones, and it is known that thiols react in a similar manner. If butanal (20) reacts with ethanethiol (CH3CH2SH) in the presence of an acid catalyst, the reaction mechanism is identical to that for the reaction with ethanol (Section 18.6) except that the sulfur of the thiol is the nucleophile. Reaction with the thiol (rather than an alcohol) leads to 65, a thioacetal. The term thio is used to show the presence of a sulfur atom rather than an oxygen atom. 

The aziridine aldehyde 56 undergoes a facile Baylis-Hillman reaction with methyl or ethyl acrylate, acrylonitrile, methyl vinyl ketone, and vinyl sulfone [60]. The adducts 57 were obtained as mixtures of syn- and anfz-diastereomers. The synthetic utility of the Baylis-Hillman adducts was also investigated. With acetic anhydride in pyridine an SN2 -type substitution of the initially formed allylic acetate by an acetoxy group takes place to give product 58. Nucleophilic reactions of this product with, e. g., morpholine, thiol/Et3N, or sodium azide in DMSO resulted in an apparent displacement of the acetoxy group. Tentatively, this result may be explained by invoking the initial formation of an ionic intermediate 59, which is then followed by the reaction with the nucleophile as shown in Scheme 43. 

Other reactions which apparently involve transfer to nucleophiles include those of [MeCo(salen)] with MeMgl to give ethane as well as methane and H2 64), and of [MeCo(DMG)2X]complexes with CN and PhNMe , apparently to give MeCN and PhNMe2 161). The mechanisms of these processes have not been studied. Nevertheless it is known that the reaction of methyl- and ethylcobalamin with cyanide (products not known) requires oxygen, and shows an induction period [see Chapter 13 of ref. 136)). 

In summary, there now exists a body of data for the reactions of carbocations where the values of kjkp span a range of > 106-fold (Table 1). This requires that variations in the substituents at a cationic center result in a >8 kcal mol-1 differential stabilization of the transition states for nucleophile addition and proton transfer which have not yet been fully rationalized. We discuss in this review the explanations for the large changes in the rate constant ratio for partitioning of carbocations between reaction with Bronsted and Lewis bases that sometimes result from apparently small changes in carbocation structure. 

The problem of the nucleophilicity of amides in glycosylation reactions is not limited to the sulfoxide method and has been shown to result in the formation of glycosyl imidates from intermolecular reaction with activated donors. It appears that this problem may be suppressed by the prior silylation of the amide [348,349]. Accordingly, it may be sufficient to operate the sulfoxide method with an excess of triflic anhydride when amides are present so as to convert all amides into O-triflyl imidates, which are then hydrolyzed on work-up. Despite these problems, several examples have been published of successful sulfoxide glycosylation reactions with acceptors carrying remote peptide bonds [344,345] and with donors coupled to resins via amide-based linkages [346,347], with no apparent problems reported. Sulfonamides and tertiary amides appear to be well tolerated by the sulfoxide method [340,350],... 

In contrast to the thermal solvolysis, a rearranged enol ether 45 (and also the hydrolysis product, acetophenone) is formed in addition to the unrearranged product 44. The rearrangement is more apparent in less nucleophilic TFE. The results are best accounted for by heterolysis to give the open primary styryl cation 46 (Scheme 8). This cation gives products of substitution 44 and elimination 30 by reaction with the solvent. Alternatively, 46 can rearrange to the a-phenyl vinyl cation 47 via 1,2-hydride shift, which gives rise to 45 and 30. 

A single reaction has been described in which a palladium-catalyzed reaction was employed to form an alkyne [45], Thus, attempted alkylation of carbonate 145 with dimethyl malonate in the presence of Pd(PPh3)4 gave a mixture of enyne 87 and the alkylation product 86 in a 15 1 ratio (Scheme 14.37). Methoxide caused an elimination in (jT-allyl)palladium intermediate 146, which is apparently faster under these conditions than a reaction with the nucleophile (cf. Eq. 14.9). The synthetic importance of this process seems to be limited. 

Pandey and co-workers have generated arene radical cations by PET from electron-rich aromatic rings [119]. The photoreaction is apparently initiated by single-electron transfer from the excited state of the arene to ground state 1,4-dicyanonaphthalene (DCN) in an aerated aqueous solution of acetonitrile. Intramolecular reaction with nucleophiles leads to anellated products regio-specifically. The author explains the regiospecifidty of the cyclization step from... 

Apparently, Eq. (29) represents a polar nonradical addition. If a two-step mechanism is conceived, intermediates of the type [XB=NRH] will be reasonable, though such cations proved to be rather unstable as isolated species (unless X represents a x-electron donating group) (33). Intermediates of the type HY—B(X)=NR would explain the fast reaction with protic bases of vanishing Bronsted acidity. The results, however, mentioned in Sections V, A, and V, C, favor to some extent the picture of iminoboranes as preferring electrophilic to nucleophilic attack. The high activity of amines can also be rationalized in terms of a concerted process, with a transition state of type VI. 

Reflecting its electronegative character, C q readily undergoes nucleophilic additions with various nucleophiles [7]. Apparently the most fundamental C-C bond forming reaction is the reaction with alkyllithium or Grignard reagents, giving the monoalkylated derivative of l,2-dihydro-C6o after protonation of the initially formed alkyl-Cso carbanion [48]. 

The lactonic property of pyran-2-ones is apparent in their reactions with nucleophiles, which normally lead to ring opening. However, this may not be simply direct attack of the reagent at the carbonyl carbon. 

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