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Section 1: Publication
Publication Type
Journal Article
Authorship
Amin Halali, Jackie Meng Xu, Charles-Francois de Lannoy
Title
Electrically conductive membranes generate hydrogen peroxide and alter local pH impacting the viability of E. Coli Biofilms
Year
2021
Publication Outlet
Industrial Engineering & Chemistry Research
DOI
ISBN
ISSN
Citation
Amin Halali, Jackie Meng Xu, Charles-Francois de Lannoy, Electrically conductive membranes generate hydrogen peroxide and alter local pH impacting the viability of E. Coli Biofilms, Industrial Engineering & Chemistry Research, 2021
Abstract
Electrically conductive membranes (ECMs) self-induce antifouling mechanisms at their surface under certain applied electrical currents. Quantifying these mechanisms is critical to enhancing ECMs’ self-cleaning performance. Local pH change and H2O2 production are among the most important self-cleaning mechanisms previously hypothesized for ECMs. However, the impacts of these mechanisms have not previously been isolated and comprehensively studied. In this study, we quantified the individual impact of electrochemically induced acidic conditions, alkaline conditions, and H2O2 concentration on model bacteria, Escherichia coli. To this end, we first quantified the electrochemical potential of carbon nanotube-based ECMs to generate stressors, such as protons, hydroxyl ions, and H2O2, under a range of applied electrical currents (±0–150 mA, 0–2.7 V). Next, these chemical stressors with similar magnitude to that generated at the ECM surfaces were imposed on E. coli cells and biofilms. In the flow-through ECM systems, biofilm viability using LIVE/DEAD staining indicated biofilm viabilities of 39 ± 9.9%, 38 ± 4.7%, 45 ± 5.0%, 34 ± 3.1%, and 75 ± 4.9% after separate exposure to pH 3.5, anodic potential (2 V), pH 11, cathodic potential (2 V), and H2O2 concentration (188 μM). Electrical current-induced pH change at the membrane surface was shown to be more effective in reducing bacterial viability than H2O2 generation and more efficient than bulk pH changes. This study identified antibiofouling mechanisms of ECMs and provides guidance for determining the current patterns that maximize their antifouling effects.
Plain Language Summary
Section 2: Additional Information
Program Affiliations
Project Affiliations
Submitters
Publication Stage
Published
Theme
Presentation Format
Additional Information
Sensor and Sensing Systems for Water Quality Monitoring 2, Refereed Publications