| Article ID | Journal | Published Year | Pages | File Type |
|---|---|---|---|---|
| 212185 | Hydrometallurgy | 2014 | 9 Pages |
•Presents dynamic microbial concentration profiles in PLS and ore-associated phase•Novel approach to decouple transport from microbial growth through modelling data•Model assumes microbial transport driven by microbial concentration gradient•Model developed using mineral leach kinetics, microbial oxidation kinetics and PBM•Model indicates that concentration gradient is not the driving force.
A model was developed to describe microbial growth and transport in the flowing bulk solution and ore-associated phases within a mineral bioleaching heap. The retention of micro-organisms was assumed to be a function of microbial transport between the ore surface and the bulk solution, as well as growth in each of these phases. Transient variations in the corresponding microbial concentrations are presented together with predicted microbial growth, transport and oxidation kinetics within the agglomerate-scale, whole ore environment. The transport model presented in this paper was developed under the assumption that the microbial concentration gradient between the identified phases was the driving force for microbial transport. Further the population balance model was super-imposed to account for available reaction surface. The model was able to predict the change in microbial concentrations in both the bulk solution and ore-associated phase. The resulting microbial transport rates to and from the ore-associated phase were found to be significantly lower than the maximum specific microbial growth rates presented, suggesting that microbial transport is not governed by the microbial concentration difference. These findings confirm the value of the modelling approach in which the population balance model is included, while demonstrating that concentration gradient as the driving force is not the main contributor to microbial transport.
