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Abstract
Biomining of valuable metals using a target specific approach promises increased purification yields and decreased cost. Target specificity can be implemented with proteins/peptides, the biological molecules, responsible from various structural and functional pathways in living organisms by virtue of their specific recognition abilities towards both organic and inorganic materials. Phage display libraries are used to identify peptide biomolecules capable of specifically recognizing and binding organic/inorganic materials of interest with high affinities. Using combinatorial approaches, these molecular recognition elements can be converted into smart hybrid biomaterials and harnessed for biotechnological applications. Herein, we used a commercially available phage-display library to identify peptides with specific binding affinity to molybdenite (MoS2) and used them to decorate magnetic NPs. These peptide-coupled NPs could capture MoS2 under a variety of environmental conditions. The same batch of NPs could be re-used multiple times to harvest MoS2, clearly suggesting that this hybrid material was robust and recyclable. The advantages of this smart hybrid biomaterial with respect to its MoS2-binding specificity, robust performance under environmentally challenging conditions and its recyclability suggests its potential application in harvesting MoS2 from tailing ponds and downstream mining processes.
Highlights
Valuable and rare earth metals exist in trace amounts as a by-product of ore processing
We demonstrate the potential application of smart biomaterials for biomining of molybdenite (MoS2)
magnetic nanoclusters (MNCs)@APTES@MoS2-P15 showed no obvious interaction with Al2O3 indicating the possible specificity of MNC-peptide system (Fig. 7). These results revealed the ability of MoS2-P15 functionalized MNCs to mine MoS2 from aqueous solutions
Summary
Valuable and rare earth metals exist in trace amounts as a by-product of ore processing. The recovery of these rare earth minerals is currently not feasible because of extensive downstream purification processes resulting in the loss of valuable resource These metals accumulate in tailing ponds, causing extensive environmental pollution. The smart biomaterial designed for biomining applications was composed of a gold-binding peptide coated on a magnetic nanoparticle (NP) core This hybrid system enabled the specific recognition and binding to gold through the peptide region and recovery of the metal from the solution with an external magnetic field. This approach allowed us to work in mild conditions and obviate hazardous chemicals. Biomining may provide a convenient and efficient tool for molybdenite recovery and contribute to meeting the ever-increasing demand of this rare metal
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