Abstract
The management of bauxite residue (BR) is a major issue for the aluminum industry because of its high alkalinity and the large volumes generated. Therefore, the recovery of rare earth elements (REEs) with or without other metals from BR and utilization of the generated residue can contribute to a solution on the management problem of BR and it can be one of the options to meet the demand of REEs. In view of the above, the selective recovery of REEs over major elements such as iron by direct acid leaching was studied initially. From the leaching results, either the recovery of REEs was low or the dissolution of iron was high. To address that, iron was removed from BR by smelting. The slag generated after smelting was leached with mineral acids. The selectivity of REEs over iron was greatly improved. However, the high level of alumina presence in BR required a large amount of fluxes thereby increasing the energy consumption in smelting. Hence, the removal (and recovery) of alumina from BR by sodium carbonate roasting was carried out. The sample, after alumina removal, was smelted and the REEs were successfully recovered from slag by leaching with mineral acids. An alternative process, called sulfation–roasting–leaching, was also developed by which the REEs can be selectively leached. The scandium recovery, however, was low. Preliminary energy and economic analysis showed that alkali roasting–smelting–leaching and sulfation–roasting–leaching were the most promising processes for the treatment of BR.
Highlights
Bauxite residue (BR, known as “red mud” in the slurry state) is a waste product generated during the Bayer process of alumina production from bauxite.[1–4] About 140 million tonnes of BR are generated annually and almost 4×109 tonnes are already stockpiled
Most of rare-earth elements (REEs) and about 90% of titanium could be leached from the quenched slag using mineral acids at a L/S ratio of 50:1, a temperature of 25◦C
It is our hope that the study of the proposed processes can contribute to the development of a near-zero-waste flow sheet for the processing of BR, including the recovery of major (Al, Fe and Ti) metals, the utilization of the residue in building applications and simultaneously the production of valuable REEs, partially decreasing the supply risk of these elements
Summary
Chenna Rao Borra∗,§,¶, Bart Blanpain†, Yiannis Pontikes†, Koen Binnemans‡, and Tom Van Gerven§. Either the recovery of REEs was low or the dissolution of iron was high. The slag generated after smelting was leached with mineral acids. The sample, after alumina removal, was smelted and the REEs were successfully recovered from slag by leaching with mineral acids. An alternative process, called sulfation– roasting–leaching, was developed by which the REEs can be selectively leached. This is an Open Access chapter published by World Scientific Publishing Company.
Sign-in/Register to view highlights & summary Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a callDisclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.
