电子废物中贵金属生物浸出可持续方法综述

IF 5.4 Q2 ENGINEERING, ENVIRONMENTAL Journal of hazardous materials advances Pub Date : 2024-05-01 DOI:10.1016/j.hazadv.2024.100435
Meghna Jaiswal, Sudhakar Srivastava
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引用次数: 0

摘要

生物采矿的发展和广泛应用是金属需求不断增长的结果。有机资源的枯竭、低品位金属矿石的丰富以及采矿和选矿过程中产生的大量金属废料,都增强了对生物采矿的需求。与高能耗和对环境不安全的传统采矿技术相比,生物采矿法是一种革命性的生物技术。它是利用微生物从低品位矿石和废料中提取有价值金属的可持续替代方法。微生物具有催化生化过程的能力,因此更容易从复杂的矿物基质中溶解和提取目标金属。值得注意的是,氧化还原过程、有机或无机酸的产生以及复合制剂的释放都是生物采矿金属所必需的。金属回收可以从金属级矿石、矿山尾矿、城市固体废弃物处理场、焚化炉灰、电子废物、焦油等中实现,所有这些都可以通过生物采矿进行有效处理。生物采矿的优势还在于它可以防止电子废物倾倒场释放出的有害气体,包括二氧化硫、氮氧化物和二氧化碳,这些都是人们关注的主要问题。在使用露天焚烧和酸浴回收有价金属时,这些气体可能会释放到环境中。如今,基本金属(铜,其次是镍和锌)和贵金属(主要是金)都是在矿石堆、搅拌罐生物反应器、垃圾场和其他地方通过微生物加工或生物采矿从矿石和矿物精矿中提取出来的。随着电子工业的蓬勃发展,处理大量电子废物的压力越来越大。考虑到贵金属在电子行业的使用以及提取贵金属的需要,这一点也非常重要。本综述讨论了生物采矿和生物浸出的原理和方法,还讨论了电子废物的总体情况,并提供了全球概览。综述主要集中于利用生物采矿从电子废物中回收有价金属。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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A review on sustainable approach of bioleaching of precious metals from electronic wastes

The development and widespread use of biomining are the result of the rising demand for metals. The depletion of organic resources, the abundance of low-grade metallic ores, and the vast production of metallic waste during mining and beneficiation processes have enhanced the need for biomining. Compared to high-energy-demanding and environmentally unsafe traditional mining techniques, the biomining approach is a revolutionary biotechnological technique. It is a sustainable alternative for extracting valuable metals from low-grade ores and waste materials by using microbes. Microbes have the capacity to catalyze biochemical processes, making it easier to solubilize and extract target metals from complicated mineral matrices. Notably, the redox processes, creation of organic or inorganic acids, and the release of complex agents are all necessary for biomining metals. Metal recovery is achieved from metallic grade ores, mine tailings, municipal solid waste disposal sites, incinerator ash, electronic wastes, tars, etc., all effectively processed via biomining. Biomining is also advantageous as it prevents the emission of harmful gases released from e-waste dump sites, including sulfur dioxides, nitrogen oxides, and carbon dioxide, which are of major concern. These gases may be released into the environment when open-air burning and acid baths are used for the recovery of valuable metals. Nowadays, both base metals (copper, and to a lesser extent, nickel and zinc) and precious metals (mainly gold) are extracted from ores and mineral concentrates in heaps, stirred-tank bioreactors, dumps, and other locations via microbial processing, or biomining. In the ongoing boom of the electronics industry, there is increasing pressure to handle huge amounts of electronic waste. This is also important considering the use of precious metals in the electronics sector and the need to extract them. The present review discusses biomining and bioleaching principles, methods, and also talks about e-waste in general, providing a worldwide overview. The review primarily concentrates on the use of biomining to recover valuable metals from electronic waste.

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来源期刊
Journal of hazardous materials advances
Journal of hazardous materials advances Environmental Engineering
CiteScore
4.80
自引率
0.00%
发文量
0
审稿时长
50 days
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