Abstract
Cellulose based nanofibers were developed by electrospinning cellulose acetate (CA) with cellulose nanocrystals (CNC) for efficient removal of methylene blue (MB) dye. The incorporation of 25% (CA-CNC 25%) and 50% CNCs (CA-CNC 50%) improved the physical and chemical properties of CA in the formed nanofibers. Adsorption at an alkaline pH of 10.5 induced deacetylation that enhanced adsorption and reusability of CA-CNC 50%, whose MB adsorption capacity was double that of neat CA. The optimum adsorption conditions using CA-CNC 50% were pH of 10.5 at 40 °C for 5 h, with an initial MB concentration of 25 mg/L. The maximum adsorption capacity of the optimized CA-CNC 50% at 1000 mg/L initial MB concentration was 316.6 mg/g. The CA-CNC 50% maintained MB removal of ≥ 80% for up to 5 cycles. Theoretical modeling and experimental data suggest that the adsorption of MB onto CA-CNC 50% can be described as endothermal chemisorption with pore diffusion being the rate-limiting of the dye mass transfer. The possible interactions that contributed to MB adsorption onto CA-CNC 50% are π-π stacking, electrostatic attraction, and hydrogen bonding, the latter of which came into effect at the onset of deacetylation.
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