Balancing Surface Chemistry and Flake Size of MXene-Based Electrodes for Bioelectrochemical Reactors

Pewee D. Kolubah; Hend Omar Mohamed; Ananda Rao Hari; Yue Ping; Mohamed Ben Hassine; Pia Dally; M. Obaid; Xiangming Xu; Jehad K. El-Demellawi; Pascal E. Saikaly; Mario Lanza; Noreddine Ghaffour; Pedro Castaño

doi:10.1002/smll.202406223

Balancing Surface Chemistry and Flake Size of MXene-Based Electrodes for Bioelectrochemical Reactors

Pewee D. Kolubah, Hend Omar Mohamed^*, Ananda Rao Hari, Yue Ping, Mohamed Ben Hassine, Pia Dally, M. Obaid, Xiangming Xu, Jehad K. El-Demellawi, Pascal E. Saikaly, Mario Lanza, Noreddine Ghaffour, Pedro Castaño^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

Abstract

MXenes have excellent properties as electrode materials in energy storage devices or fuel cells. In bioelectrochemical systems (for wastewater treatment and energy harvesting), MXenes can have antimicrobial characteristics in some conditions. Here, different intercalation and delamination approaches to obtain Ti₃C₂T_x MXene flakes with different terminal groups and lateral dimensions are comprehensively investigated. The effect of these properties on the energy harvesting performance from wastewater is then assessed. Regardless of the utilized intercalant molecules, MXene flakes obtained using soft delamination approaches are much larger (up to 10 µm) than those obtained using mechanical delamination methods (<1.5 nm), with a relatively higher content of ─O/─OH surface terminations. When employed in microbial fuel cells, electrodes made of these large MXene flakes have demonstrated a power density of over 400% higher than smaller MXene flakes, thanks to their lower charge transfer resistance (0.38 Ω). These findings highlight the crucial role of selecting appropriate intercalation and delamination methods when synthesizing MXenes for bioelectrochemical applications.

Original language	English (US)
Article number	2406223
Journal	Small
Volume	21
Issue number	20
DOIs	https://doi.org/10.1002/smll.202406223
State	Published - May 19 2025

Keywords

2D materials
antimicrobial
delamination
energy harvesting
intercalation

ASJC Scopus subject areas

Biotechnology
General Chemistry
Biomaterials
General Materials Science
Engineering (miscellaneous)

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10.1002/smll.202406223

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title = "Balancing Surface Chemistry and Flake Size of MXene-Based Electrodes for Bioelectrochemical Reactors",

abstract = "MXenes have excellent properties as electrode materials in energy storage devices or fuel cells. In bioelectrochemical systems (for wastewater treatment and energy harvesting), MXenes can have antimicrobial characteristics in some conditions. Here, different intercalation and delamination approaches to obtain Ti3C2Tx MXene flakes with different terminal groups and lateral dimensions are comprehensively investigated. The effect of these properties on the energy harvesting performance from wastewater is then assessed. Regardless of the utilized intercalant molecules, MXene flakes obtained using soft delamination approaches are much larger (up to 10 µm) than those obtained using mechanical delamination methods (<1.5 nm), with a relatively higher content of ─O/─OH surface terminations. When employed in microbial fuel cells, electrodes made of these large MXene flakes have demonstrated a power density of over 400% higher than smaller MXene flakes, thanks to their lower charge transfer resistance (0.38 Ω). These findings highlight the crucial role of selecting appropriate intercalation and delamination methods when synthesizing MXenes for bioelectrochemical applications.",

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author = "Kolubah, {Pewee D.} and Mohamed, {Hend Omar} and Hari, {Ananda Rao} and Yue Ping and Hassine, {Mohamed Ben} and Pia Dally and M. Obaid and Xiangming Xu and El-Demellawi, {Jehad K.} and Saikaly, {Pascal E.} and Mario Lanza and Noreddine Ghaffour and Pedro Casta{\~n}o",

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year = "2025",

month = may,

day = "19",

doi = "10.1002/smll.202406223",

language = "English (US)",

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AU - Kolubah, Pewee D.

AU - Mohamed, Hend Omar

AU - Hari, Ananda Rao

AU - Ping, Yue

AU - Hassine, Mohamed Ben

AU - Dally, Pia

AU - Obaid, M.

AU - Xu, Xiangming

AU - El-Demellawi, Jehad K.

AU - Saikaly, Pascal E.

AU - Lanza, Mario

AU - Ghaffour, Noreddine

AU - Castaño, Pedro

PY - 2025/5/19

Y1 - 2025/5/19

N2 - MXenes have excellent properties as electrode materials in energy storage devices or fuel cells. In bioelectrochemical systems (for wastewater treatment and energy harvesting), MXenes can have antimicrobial characteristics in some conditions. Here, different intercalation and delamination approaches to obtain Ti3C2Tx MXene flakes with different terminal groups and lateral dimensions are comprehensively investigated. The effect of these properties on the energy harvesting performance from wastewater is then assessed. Regardless of the utilized intercalant molecules, MXene flakes obtained using soft delamination approaches are much larger (up to 10 µm) than those obtained using mechanical delamination methods (<1.5 nm), with a relatively higher content of ─O/─OH surface terminations. When employed in microbial fuel cells, electrodes made of these large MXene flakes have demonstrated a power density of over 400% higher than smaller MXene flakes, thanks to their lower charge transfer resistance (0.38 Ω). These findings highlight the crucial role of selecting appropriate intercalation and delamination methods when synthesizing MXenes for bioelectrochemical applications.

AB - MXenes have excellent properties as electrode materials in energy storage devices or fuel cells. In bioelectrochemical systems (for wastewater treatment and energy harvesting), MXenes can have antimicrobial characteristics in some conditions. Here, different intercalation and delamination approaches to obtain Ti3C2Tx MXene flakes with different terminal groups and lateral dimensions are comprehensively investigated. The effect of these properties on the energy harvesting performance from wastewater is then assessed. Regardless of the utilized intercalant molecules, MXene flakes obtained using soft delamination approaches are much larger (up to 10 µm) than those obtained using mechanical delamination methods (<1.5 nm), with a relatively higher content of ─O/─OH surface terminations. When employed in microbial fuel cells, electrodes made of these large MXene flakes have demonstrated a power density of over 400% higher than smaller MXene flakes, thanks to their lower charge transfer resistance (0.38 Ω). These findings highlight the crucial role of selecting appropriate intercalation and delamination methods when synthesizing MXenes for bioelectrochemical applications.

KW - 2D materials

KW - antimicrobial

KW - delamination

KW - energy harvesting

KW - intercalation

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JF - Small

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ER -

Balancing Surface Chemistry and Flake Size of MXene-Based Electrodes for Bioelectrochemical Reactors

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Keywords

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