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Detailed thermodynamic and kinetic study of the aqueous Kolbe-Schmitt synthesis of beta-resorcylic acid has been carried out in a laboratory-scale batch reactor operated under ambient pressure. The dependence of the conversion on partial pressure of carbon dioxide (4 x 10(-4) - 1 bar), initial concentration of resorcinol (0.4-0.8 M), initial concentration of potassium bicarbonate (0.4-6 M) and temperature (348-428 K) was studied. The reaction was found to be reversible and exothermic (Delta H = -30.4 kJ/mol). Partial pressure of carbon dioxide does not influence the reaction kinetics when carried out in the excess of potassium bicarbonate (C-KHCO3,C-0/C-R,C-0 > 1). Increase of the initial concentration of potassium bicarbonate accelerates drastically the rate and shifts the equilibrium conversion to higher values. For the first time a reliable kinetic model has been proposed based on two reversible reactions of pseudo first order towards resorcinol and beta-resorcylic acid. The kinetic constants showed Arrhenius dependencies on the reaction temperature with the apparent energies of activation 105 and 125 kJ/mol for the forward and the reversed reactions, respectively. Pre-exponential factors increased with the initial concentration of potassium bicarbonate indicating a complexity of the reaction mechanism involved. The kinetic model was successfully validated against experimental data obtained under high pressure and temperature using a micro-plant. Finally, the model was found consistent with the literature data available for this reaction. (C) 2012 Elsevier B.V. All rights reserved.
Jeremy Luterbacher, Jher Hau Yeap, Bartosz Rozmyslowicz, Ahmed Mohamed Ibrahim Elkhaiary
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