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Representation of Kinetics Models in Batch Flotation as Distributed First-Order Reactions

L. Vinnett, Kristian E. Waters

2020Minerals25 citationsDOIOpen Access PDF

Abstract

Four kinetic models are studied as first-order reactions with flotation rate distribution f(k): (i) deterministic nth-order reaction, (ii) second-order with Rectangular f(k), (iii) Rosin–Rammler, and (iv) Fractional kinetics. These models are studied because they are considered as alternatives to the first-order reactions. The first-order representation leads to the same recovery R(t) as in the original domain. The first-order R∞-f(k) are obtained by inspection of the R(t) formulae or by inverse Laplace Transforms. The reaction orders of model (i) are related to the shape parameters of first-order Gamma f(k)s. Higher reaction orders imply rate concentrations at k ≈ 0 in the first-order domain. Model (ii) shows reverse J-shaped first-order f(k)s. Model (iii) under stretched exponentials presents mounded first-order f(k)s, whereas model (iv) with derivative orders lower than 1 shows from reverse J-shaped to mounded first-order f(k)s. Kinetic descriptions that lead to the same R(t) cannot be differentiated between each other. However, the first-order f(k)s can be studied in a comparable domain.

Topics & Concepts

KineticsOrder (exchange)First orderOrder of reactionRepresentation (politics)Laplace transformDomain (mathematical analysis)Derivative (finance)Inverse Laplace transformKinetic energyThermodynamicsMathematicsCombinatoricsRate equationChemistryPhysicsReaction rate constantApplied mathematicsMathematical analysisQuantum mechanicsLawPolitical scienceEconomicsPoliticsFinanceFinancial economicsMinerals Flotation and Separation TechniquesMetallurgical Processes and ThermodynamicsMineral Processing and Grinding
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