TY - JOUR
T1 - Porous Iron Electrodes Reduce Energy Consumption During Electrocoagulation of a Virus Surrogate
T2 - Insights into Performance Enhancements Using Three-Dimensional Neutron Computed Tomography
AU - Kim, Kyungho
AU - Castillo, Cesar
AU - Jang, Gyoung G.
AU - Zhang, Yuxuan
AU - Tsouris, Costas
AU - Chellam, Shankararaman
N1 - Publisher Copyright:
© 2024 The Authors. Published by American Chemical Society.
PY - 2024/10/11
Y1 - 2024/10/11
N2 - Electrocoagulation has attracted significant attention as an alternative to conventional chemical coagulation because it is capable of removing a wide range of contaminants and has several potential advantages. In contrast to most electrocoagulation research that has been performed with nonporous electrodes, in this study, we demonstrate energy-efficient iron electrocoagulation using porous electrodes. In batch operation, investigation of the external pore structures through optical microscopy suggested that a low porosity electrode with sparse connection between pores may lead to mechanical failure of the pore network during electrolysis, whereas a high porosity electrode is vulnerable to pore clogging. Electrodes with intermediate porosity, instead, only suffered a moderate surface deposition, leading to electrical energy savings of 21% and 36% in terms of electrocoagulant delivery and unit log virus reduction, respectively. Neutron computed tomography revealed the critical role of electrode porosity in utilizing the electrode’s internal surface for electrodissolution and effective delivery of electrocoagulant to the bulk. Energy savings of up to 88% in short-term operation were obtained with porous electrodes in a continuous flow-through system. Further investigation on the impact of current density and porosity in long-term operation is desired as well as the capital cost of porous electrodes.
AB - Electrocoagulation has attracted significant attention as an alternative to conventional chemical coagulation because it is capable of removing a wide range of contaminants and has several potential advantages. In contrast to most electrocoagulation research that has been performed with nonporous electrodes, in this study, we demonstrate energy-efficient iron electrocoagulation using porous electrodes. In batch operation, investigation of the external pore structures through optical microscopy suggested that a low porosity electrode with sparse connection between pores may lead to mechanical failure of the pore network during electrolysis, whereas a high porosity electrode is vulnerable to pore clogging. Electrodes with intermediate porosity, instead, only suffered a moderate surface deposition, leading to electrical energy savings of 21% and 36% in terms of electrocoagulant delivery and unit log virus reduction, respectively. Neutron computed tomography revealed the critical role of electrode porosity in utilizing the electrode’s internal surface for electrodissolution and effective delivery of electrocoagulant to the bulk. Energy savings of up to 88% in short-term operation were obtained with porous electrodes in a continuous flow-through system. Further investigation on the impact of current density and porosity in long-term operation is desired as well as the capital cost of porous electrodes.
KW - electrified treatment
KW - energy saving
KW - microbial control
KW - neutron computed tomography
KW - porous electrode
UR - http://www.scopus.com/inward/record.url?scp=85205921116&partnerID=8YFLogxK
U2 - 10.1021/acsestengg.4c00317
DO - 10.1021/acsestengg.4c00317
M3 - Article
AN - SCOPUS:85205921116
SN - 2690-0645
VL - 4
SP - 2573
EP - 2584
JO - ACS ES and T Engineering
JF - ACS ES and T Engineering
IS - 10
ER -