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Nucleophilic attack trigonal-bipyramidal transition state

Nucleophilic substitution at RSO2X is similar to attack at RCOX. Many of the reactions are essentially the same, though sulfonyl halides are less reactive than halides of carboxylic acids. The mechanisms are not identical, because a tetrahedral intermediate in this case (148) would have five groups on the central atom. Though this is possible (since sulfur can accommodate up to 12 electrons in its valence shell) it seems more likely that these mechanisms more closely resemble the Sn2 mechanism, with a trigonal bipyramidal transition state (148). There are two major experimental results leading to this conclusion. [Pg.574]

The mechanism of phosphate ester hydrolysis by hydroxide is shown in Figure 1 for a phosphodiester substrate. A SN2 mechanism with a trigonal-bipyramidal transition state is generally accepted for the uncatalyzed cleavage of phosphodiesters and phosphotriesters by nucleophilic attack at phosphorus. In uncatalyzed phosphate monoester hydrolysis, a SN1 mechanism with formation of a (POj) intermediate competes with the SN2 mechanism. For alkyl phosphates, nucleophilic attack at the carbon atom is also relevant. In contrast, all enzymatic cleavage reactions of mono-, di-, and triesters seem to follow an SN2... [Pg.210]

The regiochemistry of cleavage of the cyclic sulfite upon attack by small and large nucleophiles has been rationalized by invoking trigonal bipyramidal transition states or intermediates, as shown in transition states (38) and (39) (Scheme 2.27). [Pg.60]

The chemistry and stereochemistry of the reactions were extensively discussed in Chapter 8, sections El and E3. There is an in-line mechanism that generates a pentacovalent intermediate or transition state, with the attacking nucleophile and leaving group occupying the apical positions of the trigonal bipyramid. [Pg.585]

The incoming nucleophile attacks the phosphorus atom, and a pentacoordi-nate transition state is formed. This species has a trigonal bipyramidal geometry centered at the phosphorus atom, with the incoming nucleophile at one... [Pg.246]

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Bipyramid, trigonal

Bipyramids

Nucleophile Nucleophilic attack

Nucleophile attack

Nucleophiles attack

Nucleophilic attack

Nucleophilic attack trigonal bipyramids

Trigonal bipyramids

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