Size and structure evolution of kaolin–Al(OH) 3 flocs in the electroflocculation process: A study using static light scattering

Electroflocculation (EF) is gaining recognition as an alternative process to conventional coagulation/flocculation. The electrical current applied in EF that generates the active coagulant species creates a unique chemical/physical environment in which competing redox reactions occur, primarily wate...

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Bibliographic Details
Published in:Water research (Oxford) 2011-11, Vol.45 (18), p.6195-6206
Main Authors: Harif, T., Adin, A.
Format: Article
Language:English
Subjects:
Aluminum
Aluminum Oxide - chemistry
Applied sciences
Coagulation
electric current
Electricity
Electrochemistry - instrumentation
Electrochemistry - methods
Electrodes
Electroflocculation
electrolysis
Electrolytic cells
Evolution
Exact sciences and technology
Floc
Flocculating
Flocculation
Hydrogen-Ion Concentration
ions
Kaolin - chemistry
Light
Light scattering
Models, Chemical
Particle Size
Pollution
redox reactions
Scattering exponent
Scattering, Radiation
stainless steel
Static Electricity
Structure
Time Factors
Water treatment and pollution
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Summary:Electroflocculation (EF) is gaining recognition as an alternative process to conventional coagulation/flocculation. The electrical current applied in EF that generates the active coagulant species creates a unique chemical/physical environment in which competing redox reactions occur, primarily water electrolysis. This causes a transient rise in pH, due to cathodic formation of hydroxyl ions, which, in turn, causes a continuous shift in coagulation/flocculation mechanisms throughout the process. This highly impacts the formation of a sweep floc regime that relies on precipitation of metal hydroxide and its growth into floc. The size and structural evolution of kaolin–Al(OH) 3 flocs was examined using static light scattering techniques, in aim of elucidating kinetic aspects of the process. An EF cell was operated in batch mode and comprised of two concentric electrodes – a stainless steel cathode (inner electrode) and an aluminum anode (outer electrode). The cell was run at constant current between 0.042 A and 0.22 A, and analyses performed at pre-determined time intervals. The results demonstrate that EF is able to generate a range of flocs, exhibiting different growth rates and structural characteristics, depending on the conditions of operation. Growth patterns were sigmoidal and a linear correlation between growth rate and current applied was observed. The dependency of growth rate on current can be related to initial pH and aluminum dosing, with a stronger dependency apparent for initial optimal sweep floc regime. All flocs exhibited a fragile nature and undergo compaction and structural fluctuations during growth. This is the first time size and structural evolution of flocs formed in the EF process is reported. [Display omitted] ► Electroflocculation was performed using an aluminum anode. ► Floc evolution patterns showed stages similar to conventional flocculation. ► Floc growth was found to have a stronger dependency on higher currents. ► Higher currents applied at pH 6.5 were found to initiate higher growth rates. ► Different structural characteristics were observed, depending on operating conditions.
ISSN:0043-1354
1879-2448
DOI:10.1016/j.watres.2011.09.027