A new bioleaching strategy for the selective recovery of aluminum from multi-layer beverage cans

Used beverage cans (UBCs) represent one of the largest sources for secondary aluminum production worldwide. Beverage cans are one of the most frequently produced multi-layer packaging materials made of aluminum with an inner epoxy resin coating to prevent direct contact of food and aluminum surface. In the common way of UBCs recycling, the whole can is re-melted, resulting in the burning and loss of the inner epoxy coating. The use of acidophilic bacteria for the biological leaching of metals has already been well studied, but until now their applications for the selective separation of metal-containing multilayer materials has not been investigated. In this study, the three bioleaching bacteria: A. ferrooxidans, A. thiooxidans and A. caldus were explored to selectively leach the aluminum from the epoxy layer, resulting in leaching efficiencies of around 92% after three weeks of incubation. Surface characterization of the epoxy layer after bioleaching application revealed that the nature of the epoxy resin was unchanged, which could allow for recycling. The dissolved aluminum was afterwards selectively precipitated from the lixiviants at pH = 6.5, resulting in aluminum hydroxide precipitation efficiencies of almost 100%. The high leaching efficiencies and the selective precipitation shows the significant potential of acidophilic bacteria in the separation and recycling of multi-layer materials. (C) 2020 Elsevier Ltd. All rights reserved.

Automated summary

This study explored the use of three bioleaching bacteria to selectively leach aluminum from the epoxy layer, with leaching efficiencies reaching around 92% after three weeks of incubation. Surface characterization showed that the nature of the epoxy resin remained unchanged after bioleaching application, allowing for recycling. Selective precipitation of dissolved aluminum from lixiviants at pH = 6.5 resulted in aluminum hydroxide precipitation efficiencies of almost 100%, demonstrating the significant potential of acidophilic bacteria in the separation and recycling of multi-layer materials.