AI Article Synopsis
- - Red mud (RM), a byproduct of alumina production, is a highly alkaline waste containing critical metals, prompting researchers and industries to find efficient processing methods due to resource shortages.
- - This study explored using a moderately thermophilic bacterium to enhance the bioleaching process of metals from RM while simultaneously dealkalizing it, optimizing conditions like S:RM mass ratio and aeration rates in laboratory setups.
- - Results indicated that the optimal conditions (S:RM ratio of 2:1 and aeration at 1 L/min) led to high metal recoveries (up to 91%) and effective removal of alkaline elements like Na, K, and Ca, demonstrating the potential of this biotechnological
Article Abstract
Red mud (RM) is a highly alkaline polymetallic waste generated the Bayer process during alumina production. It contains metals that are critical for a sustainable development of modern society. Due to a shortage of global resources of many metals, efficient large-scale processing of RM has been receiving increasing attention from both researchers and industry. This study investigated the solubilization of metals from RM, together with RM dealkalization, sulfur (S) oxidation catalyzed by the moderately thermophilic bacterium . Optimization of the bioleaching process was conducted in shake flasks and 5-L bioreactors, with varying S:RM mass ratios and aeration rates. The ICP analysis was used to monitor the concentrations of dissolved elements from RM, and solid residues were analyzed for surface morphology, phase composition, and Na distribution using the SEM, XRD, and STXM techniques, respectively. The results show that highest metal recoveries (89% of Al, 84% of Ce, and 91% of Y) were achieved with the S:RM mass ratio of 2:1 and aeration rate of 1 L/min. Additionally, effective dealkalization of RM was achieved under the above conditions, based on the high rates (>95%) of Na, K, and Ca dissolution. This study proves the feasibility of using bacterially catalyzed S oxidation to simultaneously dealkalize RM and efficiently extract valuable metals from the amassing industrial waste.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC9465049 | PMC |
| http://dx.doi.org/10.3389/fmicb.2022.973568 | DOI Listing |
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