Deprotonations additives

CoO—C bond cleavage, the latter via the deprotonated addition intermediate (217 Scheme... 

Condensatfon of 57 with trans-urocanic acid chloride (62) furnished the chelated porphyrin In this case the imidazole was attached at the C-4 rather than the more common N-1 position to allow deprotonation to the imidazolate. After iron insertion and deprotonation addition of Cu(acac)2 yielded the p-imidazolato binuclear complex 64 (Scheme 24), a potential model for the [Cu5 /Cyta ] center of cytochrome oxidase. 

Another method is based on the determination of pzc both in the absence and presence of the TMIS to he mounted [1, 4]. As already explained, the surface adsorbs protons upon adsorption of anionic TMIS through coordinative bonds. Thus, its proton charge increases. This takes place at all pH values and obviously at pzc, where the surface was neutral before adsorption. Therefore, in the presence of the so-adsorbed anionic TMIS we need more hydroxyls in the solution in order to deprotonate additional surface groups and restore a zero charge at the surface. Therefore, a shift of the pzc to a higher value is rather expected. The opposite shift should be expected upon adsorption of cationic TMIS. 

There have been developed several in situ racemization reaction such as proto-nation/deprotonation, addition/elimination, oxidation/reduction and nucleophilic substitution. 

NVF failed to react with Michael acceptors containing active hydrogens, i.e., acrylic acid, acrylamide or hydroxylethyl acrylate. The cause of the poor reactivity toward these compounds has not been demonstrated, but a mechanistic rational can be suggested. The key step in the reaction is clearly addition of a nitrogen anion of NVF to the Michael acceptor. The product anion (Scheme 2) appears not to oligomerize by adding additional acrylate, but to deprotonate additional NVF. 

The situation in figure C2.8.5(b) is different in that, in addition to the mechanism in figure C2.8.5(a), reduction of the redox species can occur at the counter-electrode. Thus, electron transfer tlirough the layer may not be needed, as film growth can occur with OH species present in the electrolyte involving a (field-aided) deprotonation of the film. The driving force is provided by the applied voltage, AU. 

The TT-allylpalladium complexes 241 formed from the ally carbonates 240 bearing an anion-stabilizing EWG are converted into the Pd complexes of TMM (trimethylenemethane) as reactive, dipolar intermediates 242 by intramolecular deprotonation with the alkoxide anion, and undergo [3 + 2] cycloaddition to give five-membered ring compounds 244 by Michael addition to an electron-deficient double bond and subsequent intramolecular allylation of the generated carbanion 243. This cycloaddition proceeds under neutral conditions, yielding the functionalized methylenecyclopentanes 244[148], The syn-... 

We can extend the general principles of electrophilic addition to acid catalyzed hydration In the first step of the mechanism shown m Figure 6 9 proton transfer to 2 methylpropene forms tert butyl cation This is followed m step 2 by reaction of the car bocation with a molecule of water acting as a nucleophile The aUcyloxomum ion formed m this step is simply the conjugate acid of tert butyl alcohol Deprotonation of the alkyl oxonium ion m step 3 yields the alcohol and regenerates the acid catalyst... 

In addition to providing fully alkyl/aryl-substituted polyphosphasenes, the versatility of the process in Figure 2 has allowed the preparation of various functionalized polymers and copolymers. Thus the monomer (10) can be derivatized via deprotonation—substitution, when a P-methyl (or P—CH2—) group is present, to provide new phosphoranimines some of which, in turn, serve as precursors to new polymers (64). In the same vein, polymers containing a P—CH group, for example, poly(methylphenylphosphazene), can also be derivatized by deprotonation—substitution reactions without chain scission. This has produced a number of functionalized polymers (64,71—73), including water-soluble carboxylate salts (11), as well as graft copolymers with styrene (74) and with dimethylsiloxane (12) (75). 

KTB and KTA are superior to alkaU metal hydrides for deprotonation reactions because of the good solubiUties, and because no hydrogen is produced or oil residue left upon reaction. Furthermore, reactions of KTA and KTB can be performed in hydrocarbon solvents as sometimes requited for mild and nonpolar reaction conditions. Potassium alkoxides are used in large quantities for addition, esterification, transesterification, isomerization, and alkoxylation reactions. 

The action of nucleophilic reagents with isoxazoles can take a number of courses involving (i) nucleophilic addition to the ring (ii) nucleophilic replacement of a substituent and (iii) deprotonation. Other processes such as thermal or photochemical reactions may precede reaction with a nucleophile (see Section 4.16.3.1.2). 

In some cases acid amide formation was observed on attempted deprotonation at oxaziridine ring carbon. 2-r-Butyl-3-(4 -nitrophenyl)oxaziridine (67) was converted to the anion of acid amide (68) by sodium amide (69TL3887), while 2-(4 -nitrobenzoyl)-3-phenyl-oxaziridine (69) afforded the diacylimide (70) by addition of cyclohexylamine to its benzene solution at room temperature (67CB2593). 

Most diaziridines are not sensitive towards alkali. As an exception, diaziridines derived from 2-hydroxyketones are quickly decomposed by heating with aqueous alkali. Acetaldehyde, acetic acid and ammonia are formed from (162). This reaction is not a simple N—N cleavage effected intramolecularly by a deprotonated hydroxy group, since highly purified hydroxydiaziridine (162) is quite stable towards alkali. Addition of small amounts of hydroxybutanone results in fast decomposition. An assumed reaction path — Grob fragmentation of a hydroxyketone-diaziridine adduct (163) — is in accord with these observations (B-67MI50800). 

Solutions of unstable enols of simple ketones and aldehydes can also be generated in water by addition of a solution of the enolate to water. The initial protonation takes place on oxygen, generating the enol, which is then ketonized at a rate that depends on the solution pH. The ketonization exhibits both acid and base catalysis. Acid catalysis involves C-protonation with concerted 0-deprotonation. 

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