Non hydrogen bonding

For non-hydrogen-bonding polar compounds such as carbonyls and ethers, Tsonopoulos recommends that Eq. (2-68) be expanded to a third term that is a function of the reduced dipole moment ( I ) as described by Eqs. (2-71) through (2-73) ... 

Recent studies have found enhanced substituent solvation assisted resonance effects in dipolar non-hydrogen bonding solvents131. For several +R substituents acidities of phenols in DMSO are well correlated with their gas-phase acidities. The substituents include m- and p-SOMe, m- and p-S02Me, m-S02CF3 and m-N02. But there is very considerable enhancement of the effect of p-S02CF3, p-N02 and various other para-substituents in DMSO solution. 

Fig. 2.10 / -Amino acids used to investigate non-hydrogen-bonded structures...

The photodecomposition and thermodecomposition of nitromethane have been extensively studied as model systems in combustion, explosion and atmosphere pollution processes[l]. On another hand, nitromethane was selected as a model solvent in experiments aimed at examining non hydrogen-bonded solvent effects in a general acid-base theory of organic molecules [2.3]. This selection is based on the electronic and structural characteristics of nitromethane that has a high dielectric constant, and at the same time cannot form hydrogen bonds with solute molecules. 

Rossotti and co-workers45 introduced the term "oligomers for dimers and even multimers or ra-mers in non-aqueous solutions real examples of such self-aggregates (non-hydrogen bonded) have been reported46 for quaternary ammonium thiocyanates, iodides and perchlorates with ra-mers with n even up to 20. 

Further, in the case of virtually non-existent ion-solvent interactions (low degree of solvation), so that solute-solute interactions become more important, Kraus and co-workers47 confirmed that in dilute solutions ion pairs and some simple ions occurred, in more concentrated solutions triple ions of type M+ X M+ orX M+X andinhighly concentrated solutions even quadrupoles the expression triple ions was reserved by Fuoss and Kraus48 for non-hydrogen-bonded ion aggregates formed by electrostatic attraction. 

Noncovalent interactions, both inter- and intramolecular, are of considerable importance in determining the physical properties of molecules. Such interactions can be classified as hydrogen-bonding or non-hydrogen-bonding. In this section we will explore some recent uses of the electrostatic potential in the analysis of both types. 

The Analysis of Non-Hydrogen-Bonding Noncovaient Interactions Using Surface Electrostatic Potentials... 

Murray, J. S., K. Paulsen, and P. Politzer. 1994. Molecular Surface Electrostatic Potentials on the Analysis of Non-Hydrogen-Bonding Noncovalent Interactions. Proc. Ind. Acad. Sci. (Chem. Sci.) 106, 267. 

Cheam, T. C., and S. Krimm. 1990. Ab Initio Force Fields of Alanine Dipeptide in Four Non-Hydrogen Bonded Conformations. J. Mol. Struct. (Theochem) 206, 173-203. 

The addition of water and a non-hydrogen-bonding solvent to the reduction medium causes the reactions to shift toward the formation of alcohol products.313 For example, triethylsilane in a mixture of concentrated hydrochloric acid and acetonitrile (5 4) reduces 1-heptanal to 1-heptanol in quantitative yield after 3 hours at room temperature. In a mixture of triethylsilane in sulfuric acid, water, and acetonitrile (2 2 5), //-hep(anal gives a 97% yield of the same alcohol after 1.25 hours (Eq. 156).313... 

All these reactions are thermodynamically favourable in the direction of proton transfer to hydroxide ion but the rate coefficients are somewhat below the diffusion-limited values. In broad terms, the typical effect of an intramolecular hydrogen bond on the rate coefficient for proton removal is to reduce the rate coefficient by a factor of up to ca 105 below the diffusion limit. Correspondingly the value of the dissociation constant of the acid is usually decreased by a somewhat smaller factor from that of a non-hydrogen-bonded acid. There are exceptions, however. 

In the two examples of buffer catalysis of proton transfer from an intramolecularly hydrogen-bonded acid which have been discussed, it seems reasonably certain that the mechanism in Scheme 7 applies. The reactions are of the first order with respect to the catalyst B and it therefore follows that proton removal from the non-hydrogen-bonded species is rate-limiting k j > 2[B]- If this step consists of diffusion-controlled proton removal from a low concentration intermediate, the value k2 lx 109dm3 moP s-1 will apply for proton transfer to an amine. In the case of proton removal by hydroxide ion from 4-(3-nitrophenylazo)salicylate ion, the reaction was found to be of the first order in hydroxide ion up to the highest concentrations which could be studied (0.003 mol dm-3) with a rate... 

The ground states of the TIN and TINS stabilizers respond to the influence of the molecular environment in polymer films in almost the same manner as they do in solution. The absorption spectra of TIN in PMMA film (Figure 9) and TIN in PS film are similar to those observed for TIN in low polarity, non hydrogen-bonding solvents. A linear combination of the TIN planar) and TIN(non-planar) component spectra from the PCOMP analysis was used to fit the absorption spectrum of TIN in PMMA. 

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