引入异养铁矿石细菌作为促进电子垃圾中战略金属回收的新候选者。

Introducing heterotrophic iron ore bacteria as new candidates in promoting the recovery of e-waste strategic metals.

作者信息

Teimouri Fahimeh, Mokhtari Mehdi, Nasiri Tannaz, Abouee Ehsan

机构信息

Environmental Sciences and Technology Research Center, Department of Environmental Health Engineering, School of Public Health, Shahid Sadoughi University of Medical Sciences, Yazd, Iran.

Student Research Committee, Shahid Sadoughi University of Medical Sciences, Yazd, Iran.

出版信息

World J Microbiol Biotechnol. 2023 Mar 28;39(5):137. doi: 10.1007/s11274-023-03589-1.

DOI:10.1007/s11274-023-03589-1

PMID:36976392

Abstract

Electrical instruments are an integral part of human life resulting in a vast electronic waste generation (74.7 Mt by 2030), threatening human life and the environment due to its hazardous nature. Therefore, proper e-waste management is a necessity. Currently, bio-metallurgy is a sustainable process and an emerging research field. Simultaneous leaching of metals using two groups of indigenous heterotrophs and autotrophs was an exciting work done in this study. Bioleaching experiments using pre-adapted cultures were investigated at three e-waste densities: 5, 10, and 15 g/L. Statistical analysis was done using two-way ANOVA. Copper (93%), zinc (21.5%), and nickel (10.5%) had the highest recovery efficiencies. There was a significant difference between copper, nickel, tin, and zinc concentrations and the bacterial group (P < 0.05); Iron-oxidizing bacteria showed the most weight decrease and recovered 46-47% of total metals, mainly copper and nickel, while sulfur oxidizers were more capable of zinc leaching. The heterotrophs solubilized tin preferably and substantially decreased e-waste weight. Using heterotrophs alongside autotrophs is proposed to promote metal recovery.

摘要

电子仪器是人类生活中不可或缺的一部分，这导致了大量电子垃圾的产生（到2030年将达到7470万吨），由于其有害性质，对人类生命和环境构成威胁。因此，妥善的电子垃圾管理是必要的。目前，生物冶金是一个可持续的过程，也是一个新兴的研究领域。本研究中一项令人兴奋的工作是利用两组本土异养菌和自养菌同时浸出金属。使用预适应培养物进行生物浸出实验，研究了三种电子垃圾密度：5、10和15克/升。使用双向方差分析进行统计分析。铜（93%）、锌（21.5%）和镍（10.5%）具有最高的回收效率。铜、镍、锡和锌的浓度与细菌组之间存在显著差异（P < 0.05）；铁氧化细菌的重量减少最多，回收了46-47%的总金属，主要是铜和镍，而硫氧化剂更能浸出锌。异养菌优先溶解锡，并显著降低电子垃圾重量。建议将异养菌与自养菌一起使用以促进金属回收。

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引入异养铁矿石细菌作为促进电子垃圾中战略金属回收的新候选者。

Introducing heterotrophic iron ore bacteria as new candidates in promoting the recovery of e-waste strategic metals.

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