Double bond formation nitrogen nucleophiles

To accoimt for the enhanced values obtained in our case, one can assume that the formation in the AB2 unit of a first P = N linkage can intramolecularly activate the second B group and favors its reaction. Indeed, such a reaction leading to a P=N double bond proceeds by nucleophilic attack of the phosphane on the terminal a nitrogen atom of the azide to afford a linear phosphazide, albeit... 

Polyurethane Formation. The key to the manufacture of polyurethanes is the unique reactivity of the heterocumulene groups in diisocyanates toward nucleophilic additions. The polarization of the isocyanate group enhances the addition across the carbon—nitrogen double bond, which allows rapid formation of addition polymers from diisocyanates and macroglycols. 

For the reaction of phosphane oxide with isocyanate, the rate-determining step is the formation of the oxazaphosphetane 45 via P—O—bond formation of the intermediate betaine (44), since the stable and energetically favorable P=0 double bond is broken here. Subsequent rapid decomposition of the oxazaphosphetane 45 into iminophosphorane and carbon dioxide occurs. Within the actual aza-Wittig step, the intermediate betaine (46) is generated in a rate-determining step by nucleophilic attack of the iminophosphorane nitrogen on the carbonyl C. By P —O-bond formation, betaine (46) is then converted into an oxazaphosphetane (47), which decomposes... 

The formation of jp -carbanions adjacent to pyridine-like nitrogen in 6-membered heteroaromatic rings is complicated by the fact that with alkyl and aryllithiums, 1,2-nucleophilic addition to the azomethine double bond (Scheme 103) normally occurs in preference to metalation [88H2659, 88MI2 88T1 90H(31)1155 91AHC(52)187]. 

In the course of mechanistic studies it was established that aniline does not react with the cyclopropenones (153 and 154) even under reflux conditions. It was therefore assumed that the formation of (158) involves initial nucleophilic attack by the aminopyridine ring nitrogen on the electrophilic cyclopropenone ring. In this way 155 is formed, which is then transformed via the reactive intermediates (156, 157, and/or 161) to the prodticts. Kascheres et al. noted that the formation of 157 is formally a stereospecific trans addition of the 2-aminopyridines to the double bond of the cyclopropenone (153). Such sterospecificity has been observed in kinetically controlled Michael additions. 

Usually, the reactions of carbonyl compounds and derivatives of ammonia are considered to be concluded with the formation of the imino derivative (156), but there is evidence that the C=N double bond may react faster than the C=0 group with nitrogen nucleophiles to form 1,1-diamino derivatives (Scheme 47). 

As usual, the best strategy is to identify the nucleophile and the electrophile. This chapter introduced a new electrophile, the carbonyl carbon of an aldehyde or ketone. The nucleophiles are listed in Table 18.2. Hydride, water, HCN, and organometallic nucleophiles result in the addition of the nucleophile to the carbon and a hydrogen to the oxygen of the carbonyl group. Ylides and nitrogen nucleophiles result in the formation of a double bond between the carbonyl carbon and the nucleophile. And alcohols and thiols add two nucleophiles to the carbonyl carbon. 

As fas as reaction conditions are concerned, two main approaches are usually taken. Either the nucleophilicity of the R5OH to be added is further enhanced by addition of base (normally R50 M +, or nitrogen bases of low nucleophilicity), i.e., base catalysis, or the electrophilicity of the accepting double bond is further increased by adding, e.g., mercuric salts (alkoxymercu-ration), or sources of halonium ions (formation of / -halohydrins). Clearly, the latter protocol, from now on abbreviated as "onium-methods , necessitates a subsequent step for the removal of the auxiliary electrophile, e.g., reductive demercuration of an intermediate /i-alkoxymercu-rial. Whereas base catalysis has successfully been employed with all varieties of acceptors, application of onium-methods thus far appears to be restricted to a,/ -unsaturated carbonyl compounds. Interestingly, conjugate addition of alcohols to a,/l-enones could also be effected photochemically in a couple of cases. 

Oxidative cleavage may begin with a loss of an electron from a heteroatom or an anion. Removal of an electron creates a radical cation in the absence of a suitable nucleophile or the possibility of losing a proton, the system may be stabilized by bond cleavage and formation of a double bond in a way similar to that found in mass spectrometry [Eqs. (14) through (17)]. Sulfur is more easily oxidized that nitrogen, which loses an electron more easily than oxygen. 

The reaction of alkyllithium reagents with acyclic and cyclic tosylhydrazones can lead to mixtures of elimination (route A) and addition (route B) products (Scheme 22). The predominant formation of the less-substituted alkene product in the former reaction (Shapiro Reaction) is a result of the strong preference for deprotonation syn to the N-tosyl group. Nucleophilic addition to the carbon-nitrogen tosyl-hydrazone double bond competes effectively wiA a-deprotonation (and alkene formation) if abstraction of the a-hydrogens is slow and excess organolithium reagent is employed. Nucleophilic substitution is consistent with an Su2 addition of alkyllithium followed by electrophilic capture of the resultant carbanion. 

The nucleophilic properties of the amine nitrogen mean that the electrophilic dichlorocarbene will attack this site in a molecule. If the amine possesses another nucleophilic center, e.g. a double bond, it may compete with the carbene. Successful competition results in the formation of 1,1-dichlorocyclopropane derivatives. 

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