Effective defluoridation of industrial wastewater by using acid modified alumina in fixed-bed adsorption column: Experimental and breakthrough curves analysis

Abstract

Abstract The defluoridation performance of a simple and efficient adsorbent (SAA), developed by H2SO4 treatment of alumina, was explored in fixed-bed adsorption column (FBAC). The SAA was characterized by SEM, EDX, FTIR, XRD and Raman spectroscopy. The influence of different process affecting parameters like bed depth (2.5–7.5\xa0cm), influent flow rate (1.5–2.5\xa0mL/min), and fluoride concentration (40–60\xa0mg/L) were explored. The increased bed depth, and reduced flow rate and fluoride concentration were found to improve the column performance. The fitting of Thomas, Yoon-Nelson, Clark, BDST, and Yan models to breakthrough curves were attempted. The best fitting (R2\xa0>\xa00.9) was exhibited by Clark model. The column exhibited the maximum performance at bed depth of 7.5\xa0cm, influent flow rate of 1.5\xa0mL/min, and fluoride concentration of 40\xa0mg/L. The column performance of SAA was superior to unmodified alumina. The SAA (5\xa0g) demonstrated the successful result (% R\xa0=\xa089.76%; tb\xa0=\xa0350\xa0min; te\xa0=\xa01037\xa0min) for the treatment of industrial effluent (16.54\xa0mg/L) in FBAC. Besides, the column loaded by SAA exhibited reusability up to four cycles. These results implied the suitability of SAA for the treatment of fluoride contaminated industrial wastewater or groundwater in continuous operating mode.