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Abstract
Recycling critical metals from waste streams is increasingly important to meet the rising demand for clean energy technologies and reduce the environmental impact of ore mining. A key step in this process is the selective separation and recovery of high-grade metals from waste leachates containing complex metal mixtures; however, current strategies are limited by high chemical, energy, and resource consumption, substantial financial costs, and production of hazardous byproducts. Herein, we report the pioneering use of ferritin – self-assembling protein nanocages with porous, hollow structures and supercharged inner surfaces – as a high-efficiency biosorbent for eco-friendly, selective metal recovery from mixtures. Ferritin nanocages adsorbed cobalt (Co2+), nickel (Ni2+), and lithium (Li+) primarily through electrostatic interactions, localizing the adsorbed metal cations within their cavities. Adsorption isotherms indicated significantly more effective adsorption of Co2+ and Ni2+ compared to Li+, enabling efficient Co2+/Ni2+ separation from Li+. Leveraging ferritin's ability to concentrate adsorbed metal cations within cavities enabled selective recovery of Co2+ as nearly 95% pure solid carbonate salts from Co2+-Li+ mixtures through single-step precipitation under mild conditions, while Li+ remained in solution. This research opens new avenues for using ferritin nanocages in selective metal separation and recovery from waste streams via simple, environmentally benign adsorption-precipitation processes.
