Reactions with base and nucleophiles

The effect of having multiple, powerful electron-withdrawing groups on the same carbon is seen in the extreme case of tetranitromethane with its readiness to lose a nitro group on 

As discussed above, the nitro groups of tetranitromethane and trinitromethyl compounds are susceptible to nucleophilic attack. Both potassium iodide and alkaline hydrogen peroxide affect the reductive denitration of trinitromethyl groups to em-nitronitronates 1,1,1-trinitroethane (33) is quantitatively reduced to potassium 1,1-dinitroethane (24) on treatment with alkaline hydrogen peroxide. Nucleophiles such as potassium fluoride in DMF can displace nitrite anion from tetranitromethane. Various nucleophiles, including azide, chloride, fluoride and ethoxide have been used to displace one of the nitro groups from fluorotrinitromethane. 

The carbon-halogen bonds of l-halo-l,l-dinitroaliphatic compounds are particularly electron deficient and susceptible to nucleophilic attack. This kind of reaction is synthetically useful in the chemistry of terminal gem-dinitroaliphatic compounds. Some gem-nitronitronate 

2-Trinitrochloroethane (202) and 2,2,2-trinitroethyl acetate (203) also undergo nitro group rearrangement in the presence of potassium nitrite to give the di-potassium salt of 1,1,2,2-tetranitroethane (74) in both cases.  

Urbanski, Chemistry and Technology of Explosives, Vol. 1, Pergamon Press, Oxford (1964)  

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Reactions at carbon Reactions with Bases and Nucleophiles... 

Creary, X. Rollin, A. J. Reactions ofbicydic a-keto triflates with bases and nucleophiles. 

In common with other cationic heterocycles, the charged ring enhances the reactivity of substituents on the ring. Thus these substituents will usually be resistant to electrophilic reagents, and be susceptible to reaction with bases or nucleophilic reagents. 

Nonselective attacks at the carbon combined with a nitro group and carbon combined with the N(O) atom of the azoxy group were observed in the reaction of 4,4 -dinitroazoxyfurazan with bases and nucleophiles [468], The preparation of dinitro polyfurazans shows the great synthetic potential of the construction sequence. The simplicity and availability of the starting substances (compounds) makes this strategy a powerful method for high energetic material construction. 

Protecting groups for carboxylic acids are used to avoid reaction of the acidic COOH hydrogen with bases and nucleophiles or to prevent nucleophilic additions at the carbonyl carbon. Below are depicted several procedures for the protection of the carboxyl group by its conversion to the ester group. ... 

You first met amines in Chapter 2, and you have continued to encounter them in almost every chapter since. Chapter 20 starts by extending the coverage of amines. You have seen that amines do not undergo addition, substitution, or elimination reactions their importance lies in their reactions as bases and nucleophiles with other organic compounds. Chapter 20 also covers the reactions of aromatic heterocyclic compounds. You will see that they undergo the same reactions that benzene and substituted benzenes undergo and by the same mechanisms. 

Potassium Hydride. Potassium hydride [7693-26-7] KH, made from reaction of molten potassium metal with hydrogen at ca 200°C, is suppHed in an oil dispersion. Pressure Chemical Company (U.S.) is a principal suppHer. KH is much more effective than NaH or LiH for enolization reactions (63,64). Use of KH as a base and nucleophile has been reviewed (65). 

Electrophilicity of the S02 and SO groups (reaction with bases/nucleophiles). 

Sections I and J of Scheme 3.2 show reactions with sulfur and phosphorus nucleophiles. The reaction in Entry 25 is a useful method for introducing thiol groups. The solid thiourea is a convenient source of sulfur. A thiouronium ion is formed and this avoids competition from formation of a dialkyl sulfide. The intermediate is readily hydrolyzed by base. 

Highly stabilized phosphorus ylides are prepared from acetylenic esters, a carbon-based nucleophile, and triphenylphosphine in aqueous media.40 In acetone-water (2 1) solvent, the reaction proceeds via the conjugate addition of triphenylphosphine to dialkyl acetylenedicarboxy-lates the resulting vinyl triphenylphosphonium salts undergo Michael addition reaction with a carbon-nucleophile to give the corresponding highly stabilized phosphorus ylides. 

This has been mentioned at various points in this paper and may involve either a direct acid-base reaction of nitrene and nucleophile or, in some instances, reaction of the nitrene precursor with the nucleophile (or 1,3-dipolarophile) followed by loss of nitrogen. For example, the reaction of benzenesulphonyl azide with pyridine to give 31 (Ar=Ph) 69> could either involve a free nitrene or a concerted process in which the lone pair on the pyridine nitrogen atom assists the elimination of molecular nitrogen. That some free nitrene can be involved in these reactions is clear from the isolation of some 3-benzenesulphonamido-2,6-lutidine... 

These models refer to reactions with the simplest nucleophile, H, both under neutral conditions and in the protonated form. Chemical reactivity can be strongly altered by catalytic effects acid/base catalysis is of particular importance. We regard the studies on ga phase acidities and on proton affinities discussed in the above sections to bear special significance for quantitative modelling of acid/base catalysis in the future. 

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. 

Compound 874, as a representative of derivatives with an electron-withdrawing substituent at C-[1 of the vinyl group, is easily prepared by elimination of one benzotriazole from 2,2-/fo(benzotriazol-l-yl)ethyl methyl ketone 873. The stereoselective elimination catalyzed by NaOH gives exclusively the (E) isomer of derivative 874. Addition of nucleophiles to the double bond of vinyl ketone 874 followed by elimination of benzotriazole leads to a,P unsaturated ketones 875. Amines used as nucleophiles do not need any catalysis, but reactions with carbon and sulfur nucleophiles require addition of a base. The total effect is nucleophilic substitution of the benzotriazolyl group at the i-carbon of orji-iinsaturatcd ketone (Scheme 142) <1996SC3773>. 

The proposed mechanism involves the usual oxidative addition of the aryl halide to the Pd(0) complex affording a Pd(II) intermediate (Ar-Pd-Hal), subsequent coordination of allene 8 and migratory insertion of the allene into the Pd-C bond to form the jt-allylpalladium(II) species 123. A remarkable C-C bond cleavage of 123 leads by decarbopalladation to 1,3-diene 120 and a-hydroxyalkylpalladium species 124. /8-H elimination of 124 affords aldehyde 121 and the H-Pd-Hal species, which delivers Pd(0) again by reaction with base (Scheme 14.29). The originally expected cyclization of intermediate 123 by employment of the internal nucleophilic hydroxyl group to form a pyran derivative 122 was observed in a single case only (Scheme 14.29). 

Piperazine (13) is a base and nucleophile employed (6% in dimethylformamide) in solid-phase synthesis for removal of fluorenylmethyl-based protectors. The reaction is slower (three times) than with piperidine, but it leads to minimal aspartimide or piperazide formation. 

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