Substitution, competition with

Many problems need to be solved before chemurgic materials can be economically used as feedstocks. Among these problems are the recovery, purification, and fractionation of the diverse materials. However, none of these problems are insurmountable. Serious concerns are the supply of the raw material, the relative costs of competitive materials, and competition with other uses for the raw materials. Competition is particularly significant because materials, such as wood, could easily be used in many cases for pulping or even higher value products, such as stmctural timber. Municipal soHd waste offers a substitute raw material with few other uses (33). 

This type of addition process is particularly likely to be observed when the electrophile attacks a position that is already substituted, since facile rearomatization by deprotonation is then blocked. Reaction at a substituted position is called ipso attack. Addition products have also been isolated, however, when initial electrophilic attack has occurred at an unsubstituted position. The extent of addition in competition with substitution tends to increase on going to naphthalene and the larger polycyclic aromatic ring systems. ... 

More than 60 percent of natural gas physically consumed in the course of a year is nevertheless attributable to purchases at lower, interruptible prices by industrial boilcr-fucl users and electrical generators that are capable of substituting natural gas in off-peak months, when gas is available at prices competitive with those of black fuels (coal and heavy fuel oil). In addition to these relatively low-value, pricc-scnsitivc industrial gas uses is a wide range of intermediate-value demand categories for natural gas, such as in process and feedstock use. 

The reaction of several substituted imidazo[4,5-c/]-, pyrazolo[3,4-r/]- and triazolo[4,5-zf]pyrid-azines 3 with ynamines, in competition with [4 + 2] cycloaddition, leads to [2 + 2] derivatives 4, which rearrange to l,2-diazocines5.7 8 The reaction seems to be sensitive to the substituents, as replacement of the electron-withdrawing group R on the pyridazine ring of the pyrazolo compound (A = N, B = CH) by chlorine completely inhibits both the [4 + 2] and [2 + 2] cycloaddition reactions. The X-ray structure of the imidazo derivative 5 (R = Ms, A = CH, B = N) reveals a tub conformation of the eight-membered ring. 

Aryl radicals are produced in the decomposition of alkylazobenzenes and diazonium salts, and by f)-scission of aroyloxy radicals (Scheme 3.73). Aryl radicals have been reported to react by aromatic subsitution (e.g. of Sh) or abstract hydrogen (e.g. from MMA10) in competition with adding to a monomer double bond. However, these processes typically account for <1% of the total. The degree of specificity for tail vs head addition is also very high. Significant head addition has been observed only where tail addition is retarded by sleric factors e.g. methyl crotonate10 and -substituted methyl vinyl ketones 79, 84). 

Substitution and elimination reactions are almost always in competition with each other. In order to predict the products of a reaction, you must determine which mechanism(s) win the competition. In some cases, there is one clear winner. For example, consider a case in which a tertiary alkyl halide is treated with a strong base, such as hydroxide ... 

The kg value was determined to be about 6.9 x 10" s independent of the nature of L in 50°C decalin (AH - 31.8 kcal mol-1 AS - +20.2 cal mol 1 K l). Competition ratios k.g/ky equal to 3 and 5 were determined for L - P(OPh3)3 and PPI13, respectively under the same conditions. The second order pathway was proposed to occur via nucleophilic attack of L on the cluster, and an intermediate with a formulation the same as II/ was suggested, without supporting evidence of its existence, as a possible initial product of this nucleophilic attack. However, since fragmentation was only a minor side reaction of the substitution reactions with L - PPI13, it is quite unlikely that the photofragmentation and second order thermal substitution reactions occur via a common intermediate. 

Nitration of furfuryl alcohol (2-furylmethanol) in acetic anhydride yields the nitro-nitrate 57 which possesses both a reactive methylene group able to undergo aldol reactions, etc., and also a nitrate ion leaving group for nucleophilic substitutions.137 Detailed studies of the nitration disclose various products resulting from the addition of one or even two acetic acid residues to the furan nucleus in competition with the nitrations.138,139... 

Mg2+ is competitive with the Li+ inhibition of both postreceptor G-protein stimulation [140], and direct stimulation of adenylate cyclase [141]. Li+ inhibits Mn2+-stimulated adenylate cyclase activity in membranes in the presence, but not in the absence, of calmodulin. Since, Mn2+ can replace Ca2+ in activating calmodulin, it is likely that the observed inhibition is that of the Mn2+-dependent calmodulin stimulation of the enzyme. In the absence of calmodulin, stimulation of adenylate cyclase is probably due to substitution of Mn2+ for Mg2+ in the substrate, MnATP2+ and this is unaffected by Li+. 

Modes of cycloaddition of alkylideneallyl cation are also controlled by the reaction conditions. [4 + 3] Cycloaddition occurs in the reaction with furan. The [4 + 3] cycloaddition with furan was observed for the siloxy-substituted allyl cation 5S, but not for the methoxy-substituted allyl cation 5M. The lower electrophilicity of 5S may prefer the concerted pathway of [4 + 3] cycloaddition in competition with the stepwise pathway to yield a [3 + 2] cycloadduct and an electrophilic substitution product. 

The potential of biomass to make a large contribution towards replacing conventional fuels is constrained by land availability and competition with other end-use sectors. In particular, the potential for oil seeds to generate FAME is limited. Generally, yields of biofuels from purpose-grown crops depend on the species, soil type and climate.22 At a global level, it is estimated that biofuels could substitute up... 

A similar (but somewhat less obvious) dichotomy results in the simultaneous ring and sidechain substitution of durene. Thus in this charge-transfer nitration, the addition of N02 to the cation radical DUR+- (72) occurs in competition with its deprotonation (73), in which the pyridine has been shown to act as a base (Masnovi et al., 1989) (Scheme 15). [Note that deprotonation of DUR+- also leads to aromatic dimers via the subsequent (oxidative) substitution of the benzylic radical formed in (73) (Bewick et al., 1975 Lau and Kochi, 1984).]... 

We mentioned earlier in this section that when a sulfonyl group possesses a hydrogen on the carbon adjacent to the S02 group, an elimination-addition mechanism (193)—(194) for substitution, involving a sulfene as an intermediate, can be in competition with the direct substitution pathway and may, in fact, be preferred. Let us now discuss what is known about the mechanistic details of substitutions going by such an elimination-addition (sulfene) pathway, and the factors determining how readily such a process will occur under different conditions. 

As indicated in Chapter 8, the production of alkanes, as by-products, frequently accompanies the two-phase metal carbonyl promoted carbonylation of haloalkanes. In the case of the cobalt carbonyl mediated reactions, it has been assumed that both the reductive dehalogenation reactions and the carbonylation reactions proceed via a common initial nucleophilic substitution reaction and that a base-catalysed anionic (or radical) cleavage of the metal-alkyl bond is in competition with the carbonylation step [l]. Although such a mechanism is not entirely satisfactory, there is no evidence for any other intermediate metal carbonyl species. 

Several reactions of halogen-substituted carbon-centered radicals with silanes have been studied, but limited kinetic information is available for reactions of halogen-substituted radicals with tin hydrides. A rate constant for reaction of the perfluorooctyl radical with Bu3SnH was determined by competition against addition of this radical to styrenes, reactions that were calibrated directly by LFP methods.93 At ambient temperature, the n-C8F17 radical reacts with tin hydride two orders of magnitude faster than does an alkyl radical, consistent with the electron-deficient nature of the perflu-oroalkyl radical and the electron-rich character of the tin hydride. Similar behavior was noted previously for reactions of silanes with perhaloalkyl radicals. 

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