Abstract
This research proposes the application of iron-loaded sepiolite (S-Fe) as a catalytic adsorbent for the unreported 1-butylpyridinium chloride ([bpy] Cl) treatment in an aqueous medium. Initially, sepiolite was selected as an inexpensive and efficacious adsorbent for [bpy] Cl elimination. After that, sepiolite was loaded with iron for the subsequent electro-Fenton (EF) regeneration treatment. Once kinetic and isotherm studies were performed, providing respectively almost instantaneous adsorption (20 min) and an uptake of 22.85 mg/g, [bpy] Cl adsorption onto S-Fe was studied in continuous mode. The obtained breakthrough curve was analyzed using three standard breakthrough models, being Yoon–Nelson and Thomas the most suitable adjustments. Afterwards, S-Fe regeneration by the EF process was conducted using this iron-loaded silicate material as a heterogeneous catalyst. Under optimized operational conditions (current intensity 300 mA and Na2SO4 0.3 M), complete adsorbent regeneration was achieved in 10 h. The total mineralization of [bpy] Cl was reached within 24 h and among seven carboxylic acids detected, oxalic and acetic acids seem to be the primary carboxylic acids produced by [bpy] Cl degradation. Finally, S-Fe was efficiently used in four consecutive adsorption–regeneration cycles without a noticeable reduction in its adsorption capacity, opening a path for future uses.
Highlights
Ionic liquids (ILs) are complex salts [1], which, due to their high thermal and chemical stabilities, can accrue in the environment [2]
Sepiolite would need to be replaced or regenerated much less often than the others when working in continuous mode, making this adsorbent a much better alternative
A catalytic adsorbent was synthesized by doping sepiolite with iron
Summary
Ionic liquids (ILs) are complex salts [1], which, due to their high thermal and chemical stabilities, can accrue in the environment [2]. The potential usages of these compounds make them be widely researched and potentially used at industrial scale. Their apparition on wastewater is a matter of time [2]. The efficiency of the existing biological technologies to remove ILs is limited due to their poor biodegradability and high stability [6]. In this line, the overall objective of this study is to systematically gather information on the behavior of ILs by conventional treatments and design an eco-efficient strategy for their removal
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