R. Ramaswamy

Bio: R. Ramaswamy is an academic researcher from Indian Institute of Technology Madras. The author has contributed to research in topics: Iodate & Chemical reaction. The author has an hindex of 1, co-authored 3 publications receiving 3 citations.

Oscillations in the iodate-Mn2+ system: Apparent energy of activation

Abstract: Describes the effect of temperature on the time of oscillations and the determination of the apparent energy of activation of the overall process.

The iodate-hydrogen peroxide system: An oscillatory chemical reaction

Abstract: Certain salient features of the oscilliatory reaction in the iodate-hydrogen peroxide-manganese sulphate-malonic acid system are presented Oscillations were followed by recording the potential developed at a platinum electrode Reproducibility of the results in such a complicated system is established Evidence is provided for the periodic formation of Mn3+ in the system Effect of the concentration of the constituents as well as the effect of temperature are discussed

Limit cycle behaviour in the Belousov-Zhabotinskii oscillatory reaction

Abstract: Oscillations in the bromate-Mn(II)-organic substrate system are studied by following the concentrations of Mn(III) and Br2 spectrophotometrically, apart from monitoring the concentration of Br- by potentiometry. Limit cycles for the Mn(III)-Br2 combination are constructed experimentally and theoretically. The experimental results agree with the theoretical expectations based on a suggested mechanism.

Distinct Activation Energies for Temporal and Spatial Oscillations in the Belousov-Zhabotinskii Reaction

Abstract: Temperature dependence of the frequencies in temporal oscillations and of the moving-wave velocities of concentric waves in spatial oscillation in the Belousov-Zhabotinskii reaction was studied in detail using the same starting concentrations of the reactants. When cerium ions were used as catalyst, the activation energies were found to be 60–65 kJ/mol for the temporal oscillation and 46±4 kJ/mol for the spatial oscillation. The difference in the activation energies was well explained by the theoretical prediction based on kinetic-diffusion coupling. When [Fe(phen)32+] or [Fe(bpy)32+] was used as catalyst, the apparent activation energy in the temporal oscillation depends markedly on the concentration of the catalyst used.

Benzylmalonic acid reaction with iodine and behavior in a Briggs–Rauscher oscillator

Abstract: Benzylmalonic acid (BzMA) reacts via an enol mechanism with aqueous iodine to form rather stable iodobenzylmalonic acid. In the presence of iodate, which oxidizes iodide to di-iodine, the reaction goes to completion. The kinetics of the reaction BzMA + I2 + IO3− + H+ have been studied and the results were interpreted with a suitable mechanism. In a mixture with acidic iodate, hydrogen peroxide, and manganous ions, BzMA can serve as a substrate for a Briggs–Rauscher-type oscillating reaction. The behavior of this oscillator has been studied in detail. A mechanistic interpretation of the oscillations based on a new kinetic model is also given. © 2002 Wiley Periodicals, Inc. Int J Chem Kinet 34: 357–365, 2002

Oscillations in the bromate system with malic acid as the substrate

Abstract: The oscillation characteristics, investigated by potentiometry, of the bromate-Mn(II)/Ce(III)-malic acid system are presented. The induction period characteristic of the oscillatory system is analysed. The results are compared with the malonic acid and citric acid systems and are correlated with the difference in the rate of bromide production, proposed as the control intermediate.