Chapter 4. Metal Recovery Using Microbial Electrochemical Technologies

B. Christgen, A. Suárez, E. Milner, H. Boghani, J. Sadhukhan, Mobolaji Shemfe, Siddharth Gadkari, R. Kimber, J. Lloyd, K. Rabaey, Y. Feng, G. Premier, T. Curtis, K. Scott, E. Yu, I. Head
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Abstract

The demand for mineral and energy resources is increasing. Resources are sourced from finite geological deposits. Therefore the development of more sustainable routes is paramount. Industrial, municipal and agricultural wastewaters are potential sources of metals and energy can be recovered from oxidising waste organic matter but conventional methods are not technically or economically feasible. Bioelectrochemical systems (BES) have the potential to overcome these problems. Integrated BES can combine wastewater treatment, energy generation and resource recovery. Organic waste generated annually by humans globally contains ca. 600–1200 TWh of energy. BES can harvest energy as electricity from wastewater but the coulombic yields and power outputs are uncompetitive with alternative systems for electricity production from waste. Alternative uses of energy recovered from wastewaters by BES include resource recovery from waste streams (e.g. metals), offering wastewater treatment while valorising a waste stream for valuable product recovery. This chapter focuses on electrochemical metal recovery from wastes, noting also (bio)electrochemical synthesis of high-value organic compounds on the cathode, and biological electricity production from wastewaters at the anode. We review how fundamental microbial processes can be harnessed for resource recovery and the environmental benefits, and consider scale-up, environmental and economic costs and benefits of BES technologies for resource recovery.
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第四章。利用微生物电化学技术回收金属
对矿物和能源的需求正在增加。资源来源于有限的地质矿床。因此,开发更可持续的路线是至关重要的。工业、城市和农业废水是金属和能源的潜在来源,可以从氧化废物有机物质中回收,但传统方法在技术上或经济上都不可行。生物电化学系统(BES)有潜力克服这些问题。一体化BES可集污水处理、发电和资源回收于一体。全球人类每年产生的有机废物含有约600-1200太瓦时的能量。BES可以从废水中收集电能,但库仑产量和电力输出与其他废物发电系统相比没有竞争力。BES从废水中回收能源的替代用途包括从废物流(例如金属)中回收资源,提供废水处理,同时对废物流进行估价,以回收有价值的产品。本章着重于从废物中回收金属的电化学,还注意到阴极上高价值有机化合物的(生物)电化学合成,以及阳极上废水的生物发电。我们回顾了如何利用基本微生物过程进行资源回收和环境效益,并考虑了资源回收的规模、环境和经济成本以及BES技术的效益。
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Chapter 7. Integrating Remediation and Resource Recovery of Industrial Alkaline Wastes: Case Studies of Steel and Alumina Industry Residues Chapter 8. Conclusions Chapter 11. Applications of Engineered Nanomaterials in the Recovery of Metals from Wastewater Chapter 6. An Exploration of Key Concepts in Application of In Situ Processes for Recovery of Resources from High-volume Industrial and Mine Wastes Chapter 5. Adding Value to Ash and Digestate (AVAnD Project): Elucidating the Role and Value of Alternative Fertilisers on the Soil–Plant System
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