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Metal recovery using microbial electrochemical technologies

Metal recovery using microbial electrochemical technologies
Metal recovery using microbial electrochemical technologies

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.

1757-7039
63
87-112
Royal Society of Chemistry
Christgen, B.
0a4d9de6-88f7-48d5-b531-7a2e7f9b04e7
Suarez, A.
190a0813-813f-4ca2-b908-db283b0c9a73
Milner, E.
82a72bb5-e779-4252-992f-f95287e3b3e0
Boghani, H.
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Sadhukhan, J.
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Shemfe, M.
cced96f3-0688-499e-b221-2f2ad23ee4b5
Gadkari, S.
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Kimber, R. L.
82ea0c49-e07a-4562-8d08-71f66c68ba3e
Lloyd, J. R.
124a5842-bff6-4c68-83c4-c9598303606f
Rabaey, K.
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Feng, Y.
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Premier, G. C.
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Curtis, T.
571ecff4-a60b-4bb3-b7aa-c80d2ad1413d
Scott, K.
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Yu, E.
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Head, I. M.
45e5ea84-bd86-4ffd-a6e3-64b23dc711d2
Macaskie, Lynne E.
Sapsford, Devin J.
Mayes, Will M.
Christgen, B.
0a4d9de6-88f7-48d5-b531-7a2e7f9b04e7
Suarez, A.
190a0813-813f-4ca2-b908-db283b0c9a73
Milner, E.
82a72bb5-e779-4252-992f-f95287e3b3e0
Boghani, H.
b1f8f7d2-fcc2-4559-8210-372b17e651fc
Sadhukhan, J.
7b83ac24-93c1-445a-972c-df8b88c6dae1
Shemfe, M.
cced96f3-0688-499e-b221-2f2ad23ee4b5
Gadkari, S.
32ff24ba-eaad-4acd-82fa-fb59bb45ff0a
Kimber, R. L.
82ea0c49-e07a-4562-8d08-71f66c68ba3e
Lloyd, J. R.
124a5842-bff6-4c68-83c4-c9598303606f
Rabaey, K.
2749145e-1f8f-4fd1-9bc1-7e8072903f49
Feng, Y.
8257a816-5e4a-47bc-8aa2-e364c4d6e21e
Premier, G. C.
318775e0-df2e-4ee1-bbab-7100c0da3804
Curtis, T.
571ecff4-a60b-4bb3-b7aa-c80d2ad1413d
Scott, K.
d3e0ec37-b693-49b8-b313-8c13f259e9dd
Yu, E.
28e47863-4b50-4821-b80b-71fb5a2edef2
Head, I. M.
45e5ea84-bd86-4ffd-a6e3-64b23dc711d2
Macaskie, Lynne E.
Sapsford, Devin J.
Mayes, Will M.

Christgen, B., Suarez, A., Milner, E., Boghani, H., Sadhukhan, J., Shemfe, M., Gadkari, S., Kimber, R. L., Lloyd, J. R., Rabaey, K., Feng, Y., Premier, G. C., Curtis, T., Scott, K., Yu, E. and Head, I. M. (2019) Metal recovery using microbial electrochemical technologies. In, Macaskie, Lynne E., Sapsford, Devin J. and Mayes, Will M. (eds.) Flow Chemistry: Integrated Approaches for Practical Applications. (RSC Green Chemistry, 63, 2020-January) 63 ed. Royal Society of Chemistry, pp. 87-112. (doi:10.1039/9781788016353-00087).

Record type: Book Section

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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More information

e-pub ahead of print date: 15 October 2019
Published date: 30 October 2019
Additional Information: Publisher Copyright: © The Royal Society of Chemistry 2020.
Learn more about School of Chemistry research

Identifiers

Local EPrints ID: 498895
URI: http://eprints.soton.ac.uk/id/eprint/498895
DOI: doi:10.1039/9781788016353-00087
ISSN: 1757-7039
PURE UUID: c57700dc-6514-4b3f-a86b-06babef99385
ORCID for Y. Feng: ORCID iD orcid.org/0000-0002-6839-2106
ORCID for E. Yu: ORCID iD orcid.org/0000-0002-6872-975X

Catalogue record

Date deposited: 04 Mar 2025 17:51
Last modified: 05 Mar 2025 03:17

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Contributors

Author: B. Christgen
Author: A. Suarez
Author: E. Milner
Author: H. Boghani
Author: J. Sadhukhan
Author: M. Shemfe
Author: S. Gadkari
Author: R. L. Kimber
Author: J. R. Lloyd
Author: K. Rabaey
Author: Y. Feng ORCID iD
Author: G. C. Premier
Author: T. Curtis
Author: K. Scott
Author: E. Yu ORCID iD
Author: I. M. Head
Editor: Lynne E. Macaskie
Editor: Devin J. Sapsford
Editor: Will M. Mayes

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