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Employing conductive carrier for establishing spontaneous microbial galvanic cell and accelerating denitrification

Employing conductive carrier for establishing spontaneous microbial galvanic cell and accelerating denitrification
Employing conductive carrier for establishing spontaneous microbial galvanic cell and accelerating denitrification

It is well-known that metal corrosion is accelerated by formation of galvanic cell. In this study, we reported the acceleration of denitrification by using conductive carrier through formation of microbial galvanic cell (MGC). Electrically conductive graphite plate (GP) was used as biofilm carrier and compared with the non-conductive polypropylene (PP) plate carrier. Cyclic voltametric analyses showed that biofilms with bidirectional electron transfer functions of bioelectrochemical denitrification (BEDN) and acetate oxidation could be enriched spontaneously onto the GP carrier, hinting the establishment of MGC. Further analysis using differential pulse voltammetry revealed that the redox mediator related to extracellular electron transfer was detected in both media of the GP and PP carrier. Microbial community analysis showed that the biofilms in both GP and PP carrier had identical microbial composition but varied in abundance. The genus of Comamonas, Pseudomonas, Paracoccus and Thauera were the dominance of electroactive denitrifiers responsible for BEDN in both the GP and PP carrier. The GP carrier had a 75.9% higher abundant enrichment of electroactive denitrifiers than the PP carrier. Denitrification performance analyses showed that the GP carrier had a denitrification rate constant (kDN) of 1.25 and 2.66 h−1 at 15 °C and 30 °C, respectively, which was nearly 76.1% and 92.7% higher than the non-conductive PP carrier with corresponding values of about 0.71 and 1.38 h−1. Further, the result of conductive carrier accelerating denitrification was confirmed in scaled-up denitrification bioreactors with volume of 104 L using brush-like biofilm carriers. The acceleration of denitrification was attributed to the spontaneously established MGC, which promoted the direct and mediated electron transfer of the electroactive denitrifiers grown onto the conductive carriers and speeded up the BEDN. The result of this study demonstrated that the BEDN could be integrated to traditional biological denitrification system to accelerate denitrification in the form of MGC by simply employment of conductive carrier.

Bioelectrochemical denitrification, Conductive carrier, Extracellular electron transfer, Microbial galvanic cell, Redox mediator
0301-4797
Zhao, Wenjuan
4e389a16-9c06-4a6d-8f40-99c5dab30015
Zhao, Guodian
10e7927e-3890-4987-b9b4-f9e1b3e34e37
Jiang, Yao
d63acdcd-f47d-42c5-a658-c5d597c39816
Song, Jing
c3f6ccf2-4c63-487c-9c39-e25382b9ee91
Sharma, Preetam
acf2aca4-1c65-4c06-9f00-5f6eec40ac6e
Ramirez, Yeray Asensio
07e11818-f38e-4951-98cf-2cd8bb4d72ad
Yu, Eileen
28e47863-4b50-4821-b80b-71fb5a2edef2
Chen, Shuiliang
35b2f179-6857-4747-8a36-c8174fee6363
Zhao, Wenjuan
4e389a16-9c06-4a6d-8f40-99c5dab30015
Zhao, Guodian
10e7927e-3890-4987-b9b4-f9e1b3e34e37
Jiang, Yao
d63acdcd-f47d-42c5-a658-c5d597c39816
Song, Jing
c3f6ccf2-4c63-487c-9c39-e25382b9ee91
Sharma, Preetam
acf2aca4-1c65-4c06-9f00-5f6eec40ac6e
Ramirez, Yeray Asensio
07e11818-f38e-4951-98cf-2cd8bb4d72ad
Yu, Eileen
28e47863-4b50-4821-b80b-71fb5a2edef2
Chen, Shuiliang
35b2f179-6857-4747-8a36-c8174fee6363

Zhao, Wenjuan, Zhao, Guodian, Jiang, Yao, Song, Jing, Sharma, Preetam, Ramirez, Yeray Asensio, Yu, Eileen and Chen, Shuiliang (2022) Employing conductive carrier for establishing spontaneous microbial galvanic cell and accelerating denitrification. Journal of Environmental Management, 323, [116318]. (doi:10.1016/j.jenvman.2022.116318).

Record type: Article

Abstract

It is well-known that metal corrosion is accelerated by formation of galvanic cell. In this study, we reported the acceleration of denitrification by using conductive carrier through formation of microbial galvanic cell (MGC). Electrically conductive graphite plate (GP) was used as biofilm carrier and compared with the non-conductive polypropylene (PP) plate carrier. Cyclic voltametric analyses showed that biofilms with bidirectional electron transfer functions of bioelectrochemical denitrification (BEDN) and acetate oxidation could be enriched spontaneously onto the GP carrier, hinting the establishment of MGC. Further analysis using differential pulse voltammetry revealed that the redox mediator related to extracellular electron transfer was detected in both media of the GP and PP carrier. Microbial community analysis showed that the biofilms in both GP and PP carrier had identical microbial composition but varied in abundance. The genus of Comamonas, Pseudomonas, Paracoccus and Thauera were the dominance of electroactive denitrifiers responsible for BEDN in both the GP and PP carrier. The GP carrier had a 75.9% higher abundant enrichment of electroactive denitrifiers than the PP carrier. Denitrification performance analyses showed that the GP carrier had a denitrification rate constant (kDN) of 1.25 and 2.66 h−1 at 15 °C and 30 °C, respectively, which was nearly 76.1% and 92.7% higher than the non-conductive PP carrier with corresponding values of about 0.71 and 1.38 h−1. Further, the result of conductive carrier accelerating denitrification was confirmed in scaled-up denitrification bioreactors with volume of 104 L using brush-like biofilm carriers. The acceleration of denitrification was attributed to the spontaneously established MGC, which promoted the direct and mediated electron transfer of the electroactive denitrifiers grown onto the conductive carriers and speeded up the BEDN. The result of this study demonstrated that the BEDN could be integrated to traditional biological denitrification system to accelerate denitrification in the form of MGC by simply employment of conductive carrier.

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More information

Accepted/In Press date: 15 September 2022
e-pub ahead of print date: 21 September 2022
Published date: 1 December 2022
Additional Information: Publisher Copyright: © 2022 Elsevier Ltd
Keywords: Bioelectrochemical denitrification, Conductive carrier, Extracellular electron transfer, Microbial galvanic cell, Redox mediator
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Identifiers

Local EPrints ID: 498892
URI: http://eprints.soton.ac.uk/id/eprint/498892
DOI: doi:10.1016/j.jenvman.2022.116318
ISSN: 0301-4797
PURE UUID: ead510c6-cac3-4138-a54b-05e3529f88a0
ORCID for Eileen 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: Wenjuan Zhao
Author: Guodian Zhao
Author: Yao Jiang
Author: Jing Song
Author: Preetam Sharma
Author: Yeray Asensio Ramirez
Author: Eileen Yu ORCID iD
Author: Shuiliang Chen

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