突出古菌在城市矿山废弃物开发和估价中的作用

IF 4.6 Q2 GREEN & SUSTAINABLE SCIENCE & TECHNOLOGY Recycling Pub Date : 2023-02-04 DOI:10.3390/recycling8010020
A. Abdel Azim, Ruggero Bellini, Arianna Vizzarro, Ilaria Bassani, C. Pirri, B. Menin
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引用次数: 2

摘要

电子材料一旦被丢弃而没有再利用的意图,就会变成电子废物。由于其金属含量丰富,其中许多是关键原材料(CRM),电子垃圾可以被视为一种可开采和增值的城市矿山。普通金属精炼是通过能源密集型工艺进行的,通常基于化石燃料的使用。生物冶金是基于能够浸出含金属固体的专门微生物的生物路线的电子废物定价的一种有前途的替代方案。由于这些微生物的生理学,微生物浸出除了是一个环境可持续的过程外,在经济上也是可行的。与细菌和真菌一样,古菌也具有金属浸出活性,尽管它们的潜力被低估了。其中,极端微生物在金属回收领域的研究和应用最多,而中温物种则不太常见,但仍备受关注。在这里,我们提供了生物冶金的工业应用现状,并报告了从电子垃圾中回收金属的古菌开发技术的现状。此外,我们特别强调了产甲烷古菌,它能够将CO2转化为甲烷,以突出关键工艺(即厌氧消化、混凝土和钢铁生产)产生的富含CO2的工业流在CH4中的价值化潜力,用于天然气管网分配,同时使电子垃圾中的金属含量再次作为原料。
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Highlighting the Role of Archaea in Urban Mine Waste Exploitation and Valorisation
E-materials become e-waste once they have been discarded without the intent of reuse. Due to its rich content of metals, among which many are Critical Raw Materials (CRMs), e-waste can be considered an urban mine to exploit and valorise. Common metal refining is performed by energy-intensive processes frequently based on the use of fossil fuel. Bio-metallurgy is a promising alternative for e-waste valorisation based on biological routes of specialised microorganisms able to leach solid-containing metals. Because of the physiology of these microorganisms, microbial leaching can be economically feasible, besides being an environmentally sustainable process. Like Bacteria and Fungi, Archaea are also capable of metal leaching activity, though their potential is underestimated. Among them, the extremophiles are the most studied and applied in the field of metal recovery, while mesophilic species are less common but still of high interest. Here we provide the state of industrial application of bio-metallurgy and report on the state of the art of Archaea exploitation in metal recovery from e-waste. Moreover, we give a special highlight to methanogenic archaea, which are able to convert CO2 into methane in order to highlight the potential for the valorisation of CO2-rich industrial streams generated by key processes (i.e., anaerobic digestion, concrete, and steel production) in CH4 for gas grid distribution, while making metals content in e-waste available again as raw material.
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来源期刊
Recycling
Recycling Environmental Science-Management, Monitoring, Policy and Law
CiteScore
6.80
自引率
7.00%
发文量
84
审稿时长
11 weeks
期刊最新文献
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