Deprotonation process compounds

The measured equilibrium constants for this stepwise deprotonation scheme for Mo and W have been collected from the literature in [56]. They show that Mo is more hydrolyzed than W, and that the deprotonation sequence for Mo and W at pH = 1 reaches the neutral species M02(0H)2(H20)2. Assuming the deprotonation processes for the Sg compounds to be similar to those of Mo and W, Equations (6-9), V. Pershina and J.V. Kratz performed fully relativistic density-functional calculations of the electronic structure of the hydrated and hydrolyzed structures for Mo, W, and Sg [56]. By use of the electronic density distribution data, relative values of the free energy changes and by use of the hydrolysis model [29,30], constants of hydrolysis reactions (6-9) were defined [56]. These results show hydrolysis of the cationic species to the neutral species to decrease in the order Mo>W>Sg which is in agreement with the experimental data on hydrolysis of Mo and W, and on Sg [55] for which the deprotonation sequence may end earlier with a cationic species such as SgO(OH)3(H20)2+ that is sorbed on the cation-exchange resin. 

As a result of obtaining only one stereoisomer in the deprotonation stage of the two solvent systems, the aldehydes obtained after alkylation and hydrolysis are of opposite chirality. Consequently, it is possible to obtain an inversion of product chirality by a change in the reaction conditions, using the same chiral hydrazonic system. Nevertheless, the electrophilic substitution products are not obtained in equivalent enantiomeric excess, in spite of the high stereoselectivity in the deprotonation process, since the substitution process is so much less selective, i.e. the preference for electrophilic attack from one side of the lithium compound is not complete107. 

In the reaction of the lithium salt of 62 with acetone after a short lithiation time of 30 min, a 10% or 25% E Z mixture of 63 was obtained together with the addition product 64 in 65% yield (equation 42)65. The formation of only one addition product, and the quick disappearance of the -isomer, are due to a fast deprotonation process the -isomer compared with the Z-isomer, and the high rate of equilibration between the lithium compounds that greatly favors the syn anion, which reacts with acetone to give 64. These results point out that the formation of the syn lithium compounds is favored in oxime ethers for kinetic as well as for thermodynamic reasons. The kinetic preference, according to Ensley and Lohr65, is due to coordination between the lithium amide and the oxime oxygen. 

It was found that addition of hydroxide anion in dimethylformamide or dimethylsulfoxide to metal(II) corrole complexes results in the appearance of much sharper absorption bands relative to the starting compounds. These findings were considered consistent with the idea that an anionic, 18 Jt-electron aromatic corrole complex (e.g., 2.119) is formed as the result of what appears to be a formal deprotonation process (Scheme 2.1.25). That deprotonation actually occurs was inferred from acid-base titrations involving nickel(II) and copper(II) corroles. The conclusion that these species are anionic aromatic compounds came from an appreciation that their electronic spectra resemble those recorded for divalent metallo-porphyrins. In any event, the anion that results was found to be quenched upon acidification, regenerating the corresponding non-aromatic metallocorroles. ... 

Every review on enamines published so far includes a section dealing, however briefly, with the acid-base properties of these compounds . In our chapter we shall focus on the behaviour of enamines in protonation and deprotonation processes and try to systemize the available information on the subject, in order to shed some light on the active site involved in the processes concerned. 

ArG298 = -RT InK. This experimental scale of relative acidities was converted to a scale of absolute acidities by including certain compounds as anchor points. Thus, the gas-phase acidity of PH3 was determined to be ArG29s = 363 2 kcal/mol. The entropy change for the deprotonation process was evaluated by procedures using statistical mechanics as ArS = 24.9 2 cal - mol" K From these data the deprotonation enthalpy of PH3 at 298 K was calculated to be ArH298=PA(PHi) = 370.4 2 kcal/mol [1, 2]. 

Kinetic Currents. In kinetic currents, the limiting current is determined by the rate of a chemical reaction in the vicinity of the electrode, provided this precedes the cell reaction. Electrochem-ically inactive compounds are converted into reducible or oxidizable forms (time-dependent protonation and deprotonation processes, formation and decomposition of complexes, etc.). Conversely, during a chemical reaction after the cell reaction, the product of the electrode reaction is converted to an electrochemically inactive form without influence on the current. However, owing to the changed equilibria between the concentrations of the oxidized and reduced forms at the electrode surface, the half-wave and peak potentials are shifted (Section 25.2.1). In evaluating kinetic effects, cyclic voltammetry can be helpful (Section 25.2.4). 

Let us suppose fliat the amine is acting as a base catalyst. In fliis instance, die first step of the reaction could be the a-deprotonation of compound 2 to give enolate 4. This species would flien add to the aldehyde 1 to give intermediate 5, which after protonation would yield flie final product 3. The catalyst will be recovered unaltered at the end of flie process (Scheme 32.3). If step 1 were rate-determining, the reaction would be zero order in aldehyde and fliis is not in agreement with the kinetic law (Eq. 32.1). In consequence, the slow step should be the addition of enolate 4 to the aldehyde, and the deprotonation of 2 must be a fast pre-equilibrium. ... 

As commented above, this kind of functionalized organolithium compounds can also be prepared through deprotonation processes. The deprotonation can be also performed in a diastereoselective way, for instance, in the presence of (-)-sparteine [24]. Treatment of 0-alkyl carbamate 27 with s-BuLi in the presence of (-)-sparteine at -78 °C gave the organolithium compound 28 with high ee, which upon carboxylation and acidic hydrolysis led to (J )-pantolactone 29 (Scheme 2.5) [25],... 

Section 15 13 Thiols are compounds of the type RSH They are more acidic than alco hols and are readily deprotonated by reaction with aqueous base Thiols can be oxidized to sulfemc acids (RSOH) sulfimc acids (RSO2H) and sulfonic acids (RSO3H) The redox relationship between thiols and disul tides IS important m certain biochemical processes... 

The slow protonation rate of the conjugated anion of the sulphone (1st step) leads to the obtainment of a pseudo one-electron process. However, no self-protonatiori process exists in the presence of an excess of a proton donor of lower pK than that of the electroactive substrate and Figure 6a, curve 2 shows evidence for a two-electron step. Full substitution on the a carbon, as in the case of phenyl 2-phenylbut-2-yl sulphone, does not allow one to observe any deactivation (Figure 6b, curve 1). It is worth mentioning that cathodic deactivations of acidic substrates in aprotic solvents are rather general in electrochemistry, e.g. aromatic ketones behave rather similarly, showing deprotonation of the substrate by the dianion of the carbonyl compound. ... 

Flavin-cyclobutane pyrimidine dimer and flavin-oxetane model compounds like 1-3 showed for the first time that a reduced and deprotonated flavin is a strong photo-reductant even outside a protein environment, able to transfer an extra electron to cyclobutane pyrimidine dimers and oxetanes. There then spontaneously perform either a [2n+2n cycloreversion or a retro-Paternd-Buchi reaction. In this sense, the model compounds mimic the electron transfer driven DNA repair process of CPD- and (6-4)-photolyases. 

Bisphenol A, whose official chemical name is 2,2-bis(4-hydroxyphenyl)propane, is a difunctional monomer with two reactive hydroxyl groups, as shown in Fig. 20,2. It polymerizes svith dicarbonyl organic monomers, such as phosgene or diphenyl carbonate, which are illustrated in Fig. 20.3. During polymerization, shown in Fig. 20.4, the hydroxyl groups of the bisphenol A deprotonate in the presence of a base. After deprotonation, the oxygen atoms on the bisphenol A residue form ester bonds with the dicarbonyl compounds. The polymerization process terminates when a monohydric phenol reacts with the growing chain end. 

A major advantage of the sequence presented here is that the aldehyde group is protected at the siloxycyclopropane stage, which allows convenient storage of this stable intermediate. Of equal importance is the valuable carbanion chemistry that can be carried out a to the ester function. Efficient substitution can be achieved by deprotonation with LDA and subsequent reaction with electrophiles.12-13-6 This process makes several a-substituted [1-formyl esters available. Other ring opening variants of siloxycyclopropanes - mostly as one-pot-procedures - are contained in Scheme I. They underscore the high versatility of these intermediates for the synthesis of valuable compounds.6 Chiral formyl esters (see Table, entries 2-5) are of special... 

For the characterization of compounds extracted from plants, wool and dye baths, acquisition in the NI mode is used. The main signals in the mass spectra of each colourant are attributed to deprotonated molecular ions [M H]. More detailed studies can be performed by ESI MS" with a quadrupole ion trap mass analyzer, and such a set-up was used e.g. for the investigation of photo-oxidation processes of components of weld and onion skins.[29]... 

Also, (5-phenyl-l,3,4-oxadiazol-2-yl)-7-hydroxycoumarin is a tautomeric compound. In dilute solutions it is almost totally present in its protonated nitrogen tautomeric form. The deprotonation is a reversible process (Scheme 2). Quantum-mechanical calculations were carried out and correlated with experimental observations <2000SAA1773>. 

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