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A kinetic and mechanistic investigation of the formation of calcium sulphate in reactions that may be of use in flue-gas desulphurization I. Oxidation of CaSO 3 or of CaS with O 2 or with SO 2

1996; Royal Society; Volume: 452; Issue: 1946 Linguagem: Inglês

10.1098/rspa.1996.0030

1471-2946

D. Carl Anderson, Andrew K. Galwey,

Crystallization and Solubility Studies

A kinetic and microscopic study of the oxidation of anhydrous CaSO3 to CaSO4 in low pressures (< 700 N m-2 O2) of oxygen between 823 and 973 K is reported. The work was undertaken to investigate further the chemistry and mechanism of this reaction because of its importance in environmental protection as a method of flue-gas desulphurization. The isothermal oxidation of CaSO3 is strongly deceleratory. Rate characteristics were satisfactorily described by kinetic expressions based on rate control by a diffusion process across a barrier product CaSO4 layer of progressively increasing thickness that develops between the CaSO3 and O2 reactants. Oxidation ceased when the thickness of this barrier reached about 0.05 pm, which corresponds to about 28% reaction of the fine reactant CaSO3 crystallites. This termination of reaction before completion is ascribed to the transformation of the initial ill-crystallized product into an impermeable layer of recrystallized CaS04 that is coherent and strongly adheres to all reactant surfaces. After this partial oxidation, all surfaces of the solid are roughened by the development of irregularly disposed edges and corners of small (0.1-0.3 μm) product crystallites. The study included kinetic investigations of three related reactions (CaSO3 + SO2; CaS + O2 and CaS + SO2) that also yield CaSO4. These rate processes were satisfactorily represented by the same diffusion-controlled rate equation. Rate constants for both reactions with oxygen (+CaSO3 or CaS) agreed within experimental error. The two reactions in SO2 were relatively slower (x|) but again rate constant magnitudes were the same. The calculated activation energy for all four reactions was 125 ± 8 kJ mol-1 and all data were close to two parallel lines on the Arrhenius plot. These reactions, together with CaSO3 dissociation and disproportionation, occur in similar temperature intervals (above 800 K). We conclude that all involve similar formation and rupture steps of S-O bonds that results in facile transfer of oxygen atoms between the divalent anions involved (S2-, SO2-3 and SO2-4), oxygen and SO2. The importance of this common step in the several chemical changes investigated here is discussed in the formulation of reaction mechanisms.