Kinetics of proton transfer between metasubstituted benzoic acids and the carbinol base of crystal violet in toluene: Specific solvent effect–free metasubstituent effect on the reactivity of benzoic acids

Shrivastava

2011

Appl Magn Reson

Anomalous (reverse) substituent-induced 13 C nuclear magnetic resonance chemical shifts at the carboxyl carbon (d co ) in meta-substituted benzoic acids have been studied for 11 substituents having varying electronic effects in 4 aprotic (nonhydroxylic) solvents of varying polarity by employing different dual substituent parameter models. The regression results for apolar aprotic solvents provide a strong evidence for through space p-polarization mode of transmission of reverse metasubstituent effects on the carboxyl carbon in benzoic acids. The results for dipolar aprotic solvents indicate significant specific solvation of p-polarized forms of the acids. The study showed further that an apolar aprotic solvent has a distinct preference over a dipolar aprotic one for investigating intrinsic substituent effects on chemical shifts in aromatic molecules.

Section: Correlation Of D Co With An Acidity/reactivity Parameter Formentioning

confidence: 99%

Section: Correlation Of D Co With An Acidity/reactivity Parameter Formentioning

confidence: 99%

Influence of Aprotic Solvents on the Transmission of Anomalous Substituent Effects on 13C NMR Chemical Shifts at the Carboxyl Carbon (δco) in Meta-Substituted Benzoic Acids: A Strong Evidence for π-Polarization Mechanism

Shrivastava

2011

Appl Magn Reson

“…Using Crystal Violet carbinol as the reference base, the authors studied detailed kinetics of equilibria for 34 variously substituted benzoic acids: m ‐methyl, fluoro, chloro, bromo, iodo, methoxy, phenoxy, benzoyl, trifluoromethyl, cyano, and nitrobenzoic acids in toluene; o ‐methyl, fluoro, chloro, bromo, iodo, methoxy, ethoxy, phenoxy, acetoxy, acetyl, benzoyl, nitro, hydroxy, and aminobenzoic acids in toluene; and 2,3‐difluoro‐benzoic, 2,5‐difluoro‐benzoic, 2,6‐difluoro‐benzoic, and 3,5‐difluoro‐benzoic and dichloro‐benzoic acids along with 2‐monofluoro‐benzoic, 3‐monofluoro‐benzoic, and monochloro‐benzoic acids in chlorobenzene …”

Section: Proton Transfer Rate Equilibria In Apolar Aprotic Solvents Amentioning

confidence: 99%

“…In Eqn , k α is the catalytic constant for the monomer acid, and k β and k γ are the constants for net catalytic action by the dimeric and trimeric acid species, respectively, which may be positive or negative, with the contribution of the successive terms decreasing rapidly. The catalytic behavior is alternatively expressible as Eqn , where k cat is the composite catalytic constant and p is an acid exponent (generally p ≈ 1 except for strong enough acids for which p > 1) …”

Section: Proton Transfer Rate Equilibria In Apolar Aprotic Solvents Amentioning

confidence: 99%

“…Among these, those used by earlier researchers, for example, log K BHA (benzene) by Davis et al . and log k (chlorobenzene) by Chapman et al ., log k +1 (toluene) derived from pseudo‐first‐order reaction kinetics for mono‐substituted benzoic acids, and log K (chlorobenzene) derived from the equilibria for di‐substituted benzoic acids, are the most structure sensitive and rank as the most appropriate for defining acidity scales for the respective class of benzoic acids in inert solvents. Results of these parameters are given in Tables and .…”

Section: Proton Transfer Rate Equilibria In Apolar Aprotic Solvents Amentioning

confidence: 99%

See 1 more Smart Citation

Proton transfer reactions in apolar aprotic solvents

J of Physical Organic Chem

2015

Proton transfer reactions are advantageously investigated in low‐dielectric‐constant apolar aprotic solvents where specific solute–solvent interactions are greatly minimized, if not eliminated, and proton transfer occurs directly. An intriguing feature of these reactions is their general acid/base‐catalyzed kinetics with a timescale over microseconds to minutes. Proton‐coupled electron transfer (PCET), a great promise in the development of renewable energy sources, is an emerging application of the reactions. This article is an updated review of the post‐1980 developments in understanding the mechanism of proton transfer reactions, quantitative structure–reactivity relationships, acid/base‐catalyzed molecular rearrangements, reverse trends between acidity parameters and 13C δco (a measure of electron population at the carboxyl carbon) in aromatic carboxylic acids, coupling of proton transfer with electron transfer, and PCET reactions in suitably designed model systems in apolar aprotic solvents for renewable energy devices. Copyright © 2015 John Wiley & Sons, Ltd.

General acid catalysis in benzoic acid–Crystal Violet carbinol base reactions in toluene

Int J of Chemical Kinetics

Mishra

Rani

et al. 2012

Self Cite

Kinetics of benzoic acid-dye carbinol base reactions in an apolar aprotic solvent exhibit a complex dependence on the concentration of the acid, indicating the occurrence of general acid catalysis, the acid playing the dual role of the substrate and the catalyst. The complex kinetic behavior observed for 23 ortho-and meta-substituted benzoic acids has been traced to overlapping participations of the monomer acid, hyperacidic open chain homoconjugated complex (dimeric and trimeric) acids, and nonreactive cyclic dimer and trimer acids. It has been found that although the degree of proton transfer in the transition state is 50-60% when the acid acts exclusively in the monomeric form, it gets enhanced to as high as more than 90% when the role of homoconjugated complex acids is taken into consideration. C 2012 Wiley Periodicals, Inc. Int J Chem Kinet 44: [570][571][572][573][574][575][576] 2012