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Chlorine dioxide-iodide-malonic acid reaction

The Lengyel-Epstein model is a more realistic chemical reaction scheme. The Lengyel-Epstein model is a two-variable model for the chlorite-iodide-malonic acid (CIMA) reaction scheme and its variant, the chlorine dioxide-iodine-malonic acid (CDIMA) reaction scheme. In the model, the oscillatory behavior is related with ... [Pg.647]

The Chlorite-Iodide-Malonic Acid (CIMA) and Chlorine Dioxide-Iodine-Malonic Acid (CDIMA) Reactions... [Pg.302]

Historically, it was the CIMA reaction in which Turing patterns were first found. Under the conditions of these experiments, however, our analysis suggests that, after a relatively brief initial period, it is really the CDIMA reaction that governs the formation of the patterns. Even when the input feeds consist of chlorite and iodide, chlorine dioxide and iodine soon build up within the gel and play the role of reactants whose concentrations vary relatively slowly compared with those of C102 and I . We have therefore found it more practical to work with the CDIMA system, using chlorine dioxide and iodine along with malonic acid as the input species, since in this way the relevant parameters can more easily be measured and controlled. Working with the CDIMA system also leads us naturally toward a simpler version of the model described by eqs. (14.22)-( 14.24). [Pg.311]

The initial reagents of the CIMA reaction are chlorite (CIOJ), iodide (I ), and malonic acid (CH2(COOH)2). The overall reaction consists of the oxidation of iodide by chlorite complicated by the iodination of malonic acid. The oscillatory mechanism of the reaction was elucidated by Lengyel et al. [60]. They found that the oscillatory dynamics actually occurred when the initial chlorite and iodide ions were nearly completely consumed. Thereafter, besides the malonic acid, the major species are chlorine dioxide (CIO2) and iodine (I2) while iodide and chlorite become the true variables and play respectively the roles of the activator and of the inhibitor . [Pg.236]

The model suggests that the only role of reaction (1) is to produce iodide at a moderate speed. Therefore it should be possible to replace MA by other organics or inorganics that produce iodide from iodine at a similar rate to malonic acid. We find that oscillatory behavior occurs if ethyl acetoacetate is used for malonic acid [25]. Iodide ion can, of course, be supplied not only by a chemical reaction but also by an external input flow. We might therefore expect chlorine dioxide and iodide ion to react with oscillatory kinetics in a flow reactor even without the addition of malonic acid. Experiments [55]... [Pg.305]


See other pages where Chlorine dioxide-iodide-malonic acid reaction is mentioned: [Pg.85]    [Pg.27]    [Pg.306]    [Pg.308]   
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Chlorination reactions

Chlorine dioxide

Chlorine dioxide, reaction

Chlorine dioxide-iodide-malonic acid

Chlorine reactions

Chlorins reactions

Dioxides, reactions

Iodide reaction

Malonates, acidity

Malonic acid

Malonic acid / Malonate

Malonic acid acidity

Malonic acid acids

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