Hydrogen bonding salicylate ion

The reaction of an intramolecularly hydrogen-bonded salicylate ion with a base B is shown in (64) and the two-step mechanism for the reaction is written in Scheme 7. We can show how, according to this mechanism, the... 

The first experimental data for a reaction involving proton transfer from a hydrogen-bonded acid to a series of bases which were chosen to give ApK-values each side of ApK=0 are given in Fig. 15 (Hibbert and Awwal, 1976, 1978 Hibbert, 1981). The results were obtained for proton transfer from 4-(3-nitrophenylazo)salicylate ion to a series of tertiary aliphatic amines in aqueous solution, as in (64) with R = 3-nitrophenylazo. Kinetic measurements were made using the temperature-jump technique with spectrophoto-metric detection to follow reactions with half-lives down to 5 x 10"6s. The reciprocal relaxation time (t ), which is the time constant of the exponential... 

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 major conclusion which was reached from the work of Jarret and Saunders was that intramolecularly hydrogen-bonded protons generally give values of (p below the value for a similar proton which is not involved in an intramolecular hydrogen bond. For example, a value of (p of 0.77 was obtained for the hydrogen-bonded site in the maleate ion [12] compared to 0.94 for acetic acid. The value for the phthalate ion [10] was higher, (p = 0.95. The value of (p = 0.95 was obtained for the salicylate ion [22] in comparison to the result for phenol, tp = 1.13. 

An indication has been obtained that the opening of the salicylate hydrogen bond may become partially rate limiting in proton transfer (33) from substituted salicylate ions to hydroxide ions and buffer species in 50% (v/v) MejSO-HjO (Hibbert and Spiers, 1989a). Temperature-jump measurements of the equilibration between the salicylate ion and its dissociated species lead to curved plots of against buffer concentration and against hydroxide-ion concentration. Analysis of the results in terms of the mechanism in (33) gave the approximate values ki = 5x 10 s" and A, = 3 X 10 s ... 

In another estimate (Kirby and Percy, 1989), the carboxyl group in l-methoxymethoxy-8-naphthoic acid and the dimethylammonium group in the l-methoxymethoxy-8-A, A -dimethylnaphthylammonium ion are estimated to lead to rate increases by intramolecular catalysis of < ca. 900 and 1.9 X 10 compared to the value of ca. 1 x 10 calculated for the intramolecular catalytic effect of the carboxyl group in 2-methoxymethoxybenzoic acid. The salicylate ion remains the most efficient leaving group thus far discovered that can take part in hydrogen-bond catalysis of the hydrolysis of acetals. 

The typical detergent-dispersant additives used in modem lubricating oils are metallic detergents/sulfonates, phenolates, phosphonates, salicylates, ashless dispersants/succinimides and benzylamines. Water is solubilized by strong ion-dipole interactions. The solubilization of water (Watanabe, 1970) by hydrogen bond formation with succinimides and the amount solubilized is smaller than that solubilized by sulfonates. 

The crystallographic analysis uncovers that this compound is a molecular crystal, and the metal ion is located in the molecular symmetric center as shown in Figure 3. In the crystal cell, there are many strong hydrogen bonds between molecules as shown in Figure 4, which lead to salicylate ligands arranging each other in parallel. 

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