7 research outputs found
Recovery of metals from waste lithium ion battery leachates using biogenic hydrogen sulfide
Lithium ion battery (LIB) waste is increasing globally and contains an abundance of valuable metals that can be recovered for re-use. This study aimed to evaluate the recovery of metals from LIB waste leachate using hydrogen sulfide generated by a consortium of sulfate-reducing bacteria (SRB) in a lactate-fed fluidised bed reactor (FBR). The microbial community analysis showed Desulfovibrio as the most abundant genus in a dynamic and diverse bioreactor consortium. During periods of biogenic hydrogen sulfide production, the average dissolved sulfide concentration was 507 mg Lâ1 and the average volumetric sulfate reduction rate was 278 mg Lâ1 dâ1. Over 99% precipitation efficiency was achieved for Al, Ni, Co, and Cu using biogenic sulfide and NaOH, accounting for 96% of the metal value contained in the LIB waste leachate. The purity indices of the precipitates were highest for Co, being above 0.7 for the precipitate at pH 10. However, the process was not selective for individual metals due to simultaneous precipitation and the complexity of the metal content of the LIB waste. Overall, the process facilitated the production of high value mixed metal precipitates, which could be purified further or used as feedstock for other processes, such as the production of steel
E-waste recycling and resource recovery: A review on technologies, barriers and enablers with a focus on Oceania
Electronic e-waste (e-waste) is a growing problem worldwide. In 2019, total global production reached 53.6 million tons, and is estimated to increase to 74.7 million tons by 2030. This rapid increase is largely fuelled by higher consumption rates of electrical and electronic goods, shorter life cycles and fewer repair options. E-waste is classed as a hazardous substance, and if not collected and recycled properly, can have adverse environmental impacts. The recoverable material in e-waste represents significant economic value, with the total value of e-waste generated in 2019 estimated to be US $57 billion. Despite the inherent value of this waste, only 17.4% of e-waste was recycled globally in 2019, which highlights the need to establish proper recycling processes at a regional level. This review provides an overview of global e-waste production and current technologies for recycling e-waste and recovery of valuable material such as glass, plastic and metals. The paper also discusses the barriers and enablers influencing e-waste recycling with a specific focus on Oceania
A comparison of methods for the characterisation of waste-printed circuit boards
Electronic waste is a growing waste stream globally. With 54.6 million tons generated in 2019 worldwide and with an estimated value of USD 57 billion, it is often referred to as an urban mine. Printed circuit boards (PCBs) are a major component of electronic waste and are increasingly considered as a secondary resource for value recovery due to their high precious and base metals content. PCBs are highly heterogeneous and can vary significantly in composition depending on the original function. Currently, there are no standard methods for the characterisation of PCBs that could provide information relevant to value recovery operations. In this study, two pre-treatments, smelting and ashing of PCB samples, were investigated to determine the effect on PCB characterisation. In addition, to determine the effect of particle size and element-specific effects on the characterisation of PCBs, samples were processed using four different analytical methods. These included multi-acid digestion followed by inductively coupled plasma optical emission spectrometry (ICP-OES) analysis, nitric acid digestion followed by X-ray fluorescence (XRF) analysis, multi-acid digestion followed by fusion digestion and analysis using ICP-OES, and microwave-assisted multi-acid digestion followed by ICP-OES analysis. In addition, a mixed-metal standard was created to serve as a reference material to determine the accuracy of the various analytical methods. Smelting and ashing were examined as potential pre-treatments before analytical characterisation. Smelting was found to reduce the accuracy of further analysis due to the volatilisation of some metal species at high temperatures. Ashing was found to be a viable pre-treatment. Of the four analytical methods, microwave-assisted multi-acid digestion offered the most precision and accuracy. It was found that the selection of analytical methods can significantly affect the accuracy of the observed metal content of PCBs, highlighting the need for a standardised method and the use of certified reference material
Potential of metals leaching from printed circuit boards with biological and chemical lixiviants
The generation of electronic waste (e-waste) is an issue with global consequences and therefore the proper management and recycling of e-waste are of increasing importance. Printed circuit boards (PCBs), which are a common component of e-waste, have a high valuable metal content which also makes this material an important secondary resource. In this study, biohydrometallurgical extraction of metals from PCBs was investigated as a potential alternative to conventional hydrometallurgical or pyrometallurgical processing options. An indirect non-contact leaching approach using ferric iron generated by Acidithiobacillus ferrooxidans was compared to chemical ferric sulfate leaching of Cu, Ni, Zn and Al from milled high-grade PCBs at 1% pulp density at Fe3+ concentrations of 5â20 g Lâ1 and at a pH range of 0.6â1.2. The roles of redoxolysis and acidolysis were examined by comparing ferric leaching with sulfuric acid leaching conducted at initial pH values of 0.8â1.4. Results showed that the supplementation of ferric iron significantly (p < 0.05) improved the chemical leaching yields as compared to sulfuric acid leaching for Cu (47.4% to 66.3%), Al (55.3% to 100%), Zn (45.5% to 92.4%) and Ni (61.0% to 97.7%) at pH 0.8. Increase in ferric iron concentration and decrease in pH also significantly (p < 0.05) improved the yield for both biological and chemical leaching. The optimal condition for overall metal bioleaching was at 20 g Lâ1 ferric iron at an initial pH of 0.6, yielding 87% for Cu and 100% for Al, Zn and Ni. Since no significant variation was found between chemical ferric sulfate and biogenic ferric sulfate leaching at a majority of the tested ferric concentrations, this study suggested that using biogenic lixiviants for extracting metals from PCBs is a viable alternative to chemical leaching