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Relevant academic research and scientific papers

Ionizing power of aprotic solvents

Rate constants for the heterolysis reactions (SN1) of a series of chloro-diarylmethanes in aprotic solvents (dimethyl sulfoxide (DMSO), acetonitrile, carboxamides, etc.) have been determined conductometrically in the presence of amines or triphenylphosphane, which trap the intermediate ion-pairs and suppress ion recombination. The operation of SN2 mechanisms can be excluded because the observed first-order rate constants become almost independent of the nature of the nucleophilic additive when a certain concentration of nucleophile is exceeded. The heterolysis rate constants are used to calculate nucleofugality parameters Nf and sf for chloride in aprotic solvents according to the linear free-energy relationship lgak (25 °C) = sf(Nf + Ef). Ionizing powers YBnCl of these solvents were calculated according to the Winstein-Grunwald equation. Because the heterolysis rate constants in aprotic solvents correlate only poorly with dielectric constants or empirical solvent parameters such as Gutmann's acceptor numbers or ETN values, the most common solvent polarity parameters do not reliably predict ionization rates in aprotic solvents. The kinetics of the heterolyses of chloro-diarylmethanes in aprotic solvents have been studied conductometrically by suppressing ion recombination with amine additives. In this way it became possible to determine the ionizing power of aprotic solvents and compare them to those of protic solvents. Copyright

Suppression of common-ion return by amines: A method to measure rates of fast SN1 reactions

(Chemical Equation Presented) Rate constants for solvolyses of benzhydryl chlorides, which take place on the 10 ms to minute time scale, have been determined in aqueous acetone and acetonitrile by conductometry, using conventional conductometers as well as stopped-flow techniques. Secondary and tertiary amines were used to suppress ion recombination (common-ion return) thus giving access to the ionization rate constants k1. The observed common-ion rate depressions can be rationalized by the correlation equation for electrophile-nucleophile combinations, log k(20 °C) = s(E + N), where electrophiles (here: carbocations) are characterized by the parameter Eand nucleophiles (here: chloride anions and solvents) are characterized by N and s. 2009 American Chemical Society.

Thermochemical Study of the Addition of Carbenium Ions to Alkenes

Scales of carbenium ion stabilities have been obtained from 1H NMR equilibrium studies of mixtures of partly ionized para-substituted diarylmethyl chlorides in CD2Cl2/BCl3 at -70 deg C and via calorimetric determination of the heats of ionization (ΔHi) of the alkyl chlorides (Ar2CHCl + BCl3 -> Ar2CH+BCl4-) in CH2Cl2/BCl3 at -70 deg C.The heats of the reactions of diarylmethyl tetrachloroborates with 2-methyl-1-pentene (Ar2CH+BCl4- + CH2=C(CH3)C3H7 -> Ar2CHCH2C(CH3)ClC3H7 + BCl3), which were determined by low-temperature calorimetry, increase from -53.1 kJ/mol for (H3CC6H4)2CH+BCl4- to -33.0 kJ/mol for the better stabilized (H3COC6H4)(H3CC6H4)CH+BCl4-.In contrast, the heats (ΔHa) of the Lewis acid catalyzed additions of the corresponding para-substituted diarylmethyl chlorides to 2-methyl-1-pentene are independent of the para substituents (ΔHa=-86.5 +/-2.7 kJ/mol).Similar values of ΔHa were obtained for the addition of p-anisylphenylmethyl chloride to trimethylethylene, styrene, β-methylstyrene, and isoprene. ΔHa is predominantly determined by the conversion of a ?(C=C) into a ?(C-C) bond, and the heats of addition of diarylmethyl tetrachloroborates to alkenes in CH2Cl2 are given by the equation ΔHb=(9.5 +/- 6.3 pKR+) kJ/mol.

Ionisation and Dissociation of Diarylmethyl Chlorides in BCl3/CH2Cl2 Solution: Spectroscopic Evidence for Carbenium Ion Pairs

The ionisation equilibria of diarylmethyl chlorides Ar2CHCl (Ar = p-CH3O-C6H4, p-PhO-C6H4, p-CH3-C6H4) reacting with BCl3 in CH2Cl2 to give ion-pairs Ar2CH(+)BCl4(-) (KI), and the dissociation of these (KD) were studied by conductimetry and spectro-photometry.The molar conductivities are almost independent of the nature of the aryl group (ca. 3.5E-3 Sm2/mol at -70 deg C).The ionisation constants KI increase strongly with increasing electron releasing ability of the p-substituents.The standard ionisation enthalpies and entropies for (p-CH3-C6H4)2CHCl and (p-PhO-C6H4)(Ph)CHCl, calculated from the KI at different temperatures are negative.The dissociation constants KD do not show a systematic dependence on the electron donating abilities of the substituents in the aryl groups.Small differences between the UV-vis absorption spectra of unpaired and paired ions were used to confirm the conductimetrically determined values of KD. - Key words: Carbocations / Electrochemistry / Ionisation / Spectroscopy, Visible / Thermodynamics