Fluoride removal by hybrid cation exchanger impregnated with hydrated Al(III) oxide nanoparticles (HCIX-Al) with novel closed-loop recyclable regeneration system

A high concentrations of fluoride (F-) in groundwater limits drinking water supplies and results in fluorosis for hundreds of millions of people globally. A novel F- selective adsorbent (HCIX-Al) with a closed-loop regeneration system was developed, characterized, and assessed for its effectiveness...

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Bibliographic Details
Published in:Reactive & functional polymers 2021-12, Vol.169, p.105067, Article 105067
Main Authors: Tangjitjaroenkit, Sutawan, Pranudta, Antika, Chanlek, Narong, Nguyen, Trung Thanh, Kuster, Anootnara T., Kuster, Anthony C., El-Moselhy, Medhat Mohamed, Padungthon, Surapol
Format: Article
Language:English
Subjects:
Acids
Aluminum
Aluminum chloride
Aluminum oxide
Calcium ions
Cationic polymerization
Closed-loop regeneration
Defluoridation
Drinking water
Fluoride (F-) adsorption
Functional groups
Groundwater
Groundwater treatment
Hydrated Al(III) oxide
Hydrogen ions
Ion exchange
Ion exchangers
Luminescence
Nanoparticles
Regeneration
Sorbents
Sorption
Sulfonic acid
Wastewater
Water supply
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Summary:A high concentrations of fluoride (F-) in groundwater limits drinking water supplies and results in fluorosis for hundreds of millions of people globally. A novel F- selective adsorbent (HCIX-Al) with a closed-loop regeneration system was developed, characterized, and assessed for its effectiveness in F- removal using both synthetic and natural groundwater. The system used an inexpensive polymeric macroporous cation exchanger doped with hydrous aluminum oxide (HAlO) nanoparticles. The HAlO nanoparticles were loaded into the matrix of the polymer phase by ion-exchange reactions between Al3+ and Ca2+ ions that bind with sulfonic acid functional groups of the cation exchangers. Hydrogen ions were generated in-situ during the HAlO formation process, creating acidic conditions inside the polymeric phase, which significantly increased F- sorption capacity (maximum sorption capacity = 5.75 mg/g at pH 7.5). While most other aluminum oxide-based F- selective sorbents suffer from low F- removal capacity at neutral to alkaline pH of typical groundwater, the HCIX-Al exhibited high F- sorption capacity even using alkaline (pH 8.5) groundwater. The treated water had a pH greater than 6.5 and non-detectable levels of aluminum (detection limit 0.002 mg/L), which complies with drinking water regulations. The HCIX-Al material can be reused by conditioning the exhausted material with a closed-loop regeneration chemical containing a recyclable 12% AlCl3 solution. The F- was precipitated from the regeneration system as CaF2 using lime at pH 11. This material, including a novel regeneration scheme, offered high F- removal capacity, cost-effectiveness, and provided a sustainable defluoridation process. [Display omitted] •The fluoride-selective hybrid nano-adsorbent, HCIX-Al, were firstly synthesized.•High F- sorption capacity can be achieved even at mildly alkaline groundwater.•Cation exchanger was used as support with an insignificant Donnan membrane effect.•Cost-effective closed-loop recyclable regenerant solution was proposed.•The HCIX-Al was extensively validated using both synthetic and field test water.
ISSN:1381-5148
1873-166X
DOI:10.1016/j.reactfunctpolym.2021.105067