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Issue
Korean Journal of Chemical Engineering,
Vol.39, No.7, 1919-1926, 2022
High potential of amine rice husk magnetic biocomposites for Cu(II) ion adsorption and heterogeneous degradation of contaminants in aqueous solution
Nata IF, Wicakso DR, Mirwan A, Irawan C, Juwita R, Astuti NA, An-Nisa RT
Rice husk (RH) cellulose as a matrix was synthesized for amine rice husk magnetic biocomposite (RBNH2) by one-pot solvothermal method. The synergic effect of amine on magnetic nanoparticle will enhance the reactivity of material. Ethylene glycol as solvent was used for dissolved iron(III) chloride hexahydrate, Na-acetate anhydrate, and 1,6-hexanediamine, then RH was added, kept at ±200 ℃ for 6 h. The optimums of Fe contained and amine concentrations on biocomposite were detected at 93% and 2.9mmol/g, respectively. The surface area of rice husk significantly increased from 1.309m2 g-1 to 19.45m2 g-1 when converted to biocomposite. The RB-NH2 has good capability to adsorb Cu(II) ion at 116.45mg g-1 at pH 5 for 60min. Surprisingly, during adsorption, the RB-NH2 also worked on reducing the chemical oxygen demand (COD) number, total suspended solid (TSS) and dye for 22%, 54.37%, and 33.74%, respectively. The reuse effectiveness for RB-NH2 showed a good result with four repetitions. The multiple effects of amine rice husk magnetic biocomposite on wastewater contaminants leads to becoming a candidate material to be developed and applied in a wide range of waste water treatment applications.
Keywords: Adsorption; Biocomposite; Cu(II) Ion; Magnetic; Rice Husk; Solvothermal
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