Soda-ash roasting of the chromite mineral is commonly used worldwide for th
e production of water-soluble sodium chromate. The formation of sodium chro
mate during the soda-ash roasting reaction depends on the oxygen partial pr
essure and availability of oxygen at the reaction front. The effects of tem
perature, oxygen partial pressure, charge composition, and their roles on t
he overall roasting reaction were studied in order to analyze the reaction
mechanism. The influence of process parameters such as the addition of alka
li and process residue as the filler material on the overall reaction rate
is discussed. The rate-determining steps for the soda-ash roasting reaction
are analyzed. The importance of the binary Na2CO3-Na2CrO4 liquid phase dur
ing the reaction in determining its speed is also examined. It is shown tha
t the experimental results for the roasting reaction can be best described
by the Ginstling and Brounshtein (GB) equation for diffusion-controlled kin
etics. From the measured kinetics data, the apparent activation energy for
the roasting reaction was calculated to be between 180 and 190 kJ.mol(-1) i
n the temperature range from 1023 to 1210 K and between 35 and 40 kJ.mol(-1
) above 1210 K.