TY - JOUR
T1 - Electro-catalytic membrane reactors for the degradation of organic pollutants-A review
AU - Kumari, Priyanka
AU - Bahadur, Nupur
AU - Cretin, Marc
AU - Kong, Lingxue
AU - O'Dell, Luke A.
AU - Merenda, Andrea
AU - Dumée, Ludovic F.
N1 - Funding Information:
LFD acknowledges the support from Khalifa University through project RC2-2019-007.
Publisher Copyright:
© The Royal Society of Chemistry.
PY - 2021/9
Y1 - 2021/9
N2 - The occurrence and accumulation of persistent organic pollutants (POPs) in wastewater represent global challenges since they are bio-refractory pollutants, which cannot be remediated with classical wastewater treatment systems. Amongst emerging technologies, POPs may be treated by electrochemical advanced oxidation processes to remediate selective contaminants through specific degradation pathways. Although dense anodic electrodes have been extensively employed in such electrochemical processes, the surface and bulk properties of such electrodes limit the mass transfer and degradation rates of these pollutants, opening the route to the application of porous electrode materials, referred to as electro-catalytic membrane reactors (ECMRs). The application of ECMRs facilitates the degradation of these compounds, while also simultaneously allowing for fine filtration operation. This paper is focussed on discussing the recent development and preparative methods of anodic membranes, and the catalytic performance of these membranes for degradation of organics in wastewater. The effect of physicochemical characteristics such as the surface area, porosity, and morphology on the catalytic performance of the membranes is elaborated. A summary of the most relevant electro-catalytic membrane materials and parameters, which contribute to the electrocatalytic process optimisation, is presented, to investigate the impact of the material properties on the catalytic rate of the reaction for efficient output. Therefore, this aims at critically assessing the properties of electrocatalytic membranes used in ECMR, mechanisms involved in degradation of organic pollutants and optimal parameters to carry out electrocatalytic reactions, which helps in identifying and bridging the research gaps for the large scale employment of ECMRs in wastewater remediation.
AB - The occurrence and accumulation of persistent organic pollutants (POPs) in wastewater represent global challenges since they are bio-refractory pollutants, which cannot be remediated with classical wastewater treatment systems. Amongst emerging technologies, POPs may be treated by electrochemical advanced oxidation processes to remediate selective contaminants through specific degradation pathways. Although dense anodic electrodes have been extensively employed in such electrochemical processes, the surface and bulk properties of such electrodes limit the mass transfer and degradation rates of these pollutants, opening the route to the application of porous electrode materials, referred to as electro-catalytic membrane reactors (ECMRs). The application of ECMRs facilitates the degradation of these compounds, while also simultaneously allowing for fine filtration operation. This paper is focussed on discussing the recent development and preparative methods of anodic membranes, and the catalytic performance of these membranes for degradation of organics in wastewater. The effect of physicochemical characteristics such as the surface area, porosity, and morphology on the catalytic performance of the membranes is elaborated. A summary of the most relevant electro-catalytic membrane materials and parameters, which contribute to the electrocatalytic process optimisation, is presented, to investigate the impact of the material properties on the catalytic rate of the reaction for efficient output. Therefore, this aims at critically assessing the properties of electrocatalytic membranes used in ECMR, mechanisms involved in degradation of organic pollutants and optimal parameters to carry out electrocatalytic reactions, which helps in identifying and bridging the research gaps for the large scale employment of ECMRs in wastewater remediation.
UR - http://www.scopus.com/inward/record.url?scp=85114013095&partnerID=8YFLogxK
U2 - 10.1039/d1re00091h
DO - 10.1039/d1re00091h
M3 - Review article
AN - SCOPUS:85114013095
SN - 2058-9883
VL - 6
SP - 1508
EP - 1526
JO - Reaction Chemistry and Engineering
JF - Reaction Chemistry and Engineering
IS - 9
ER -