Fluoride Removal from Aqueous Solutions Using Poly(Styrene Sulfonate)/Nanoalumina Multilayer Thin Films

Prathna, T.C.; Raichur, Ashok M.

doi:10.1002/gch2.201700064

Cited by 5 publications

(1 citation statement)

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“…(Johansson, Paul, Nys, & Roberts, ; Liu, Yang, Wen, & Liu, ; Senthilkumar, Vijayaraghavan, Thilakavathi, Iyer, & Velan, ). Furthermore, it is critically observed that the aluminum‐impregnated adsorbents such as nano‐alumina multilayer thin films, granular zirconium–aluminum, aluminum‐impregnated coconut fiber, and aluminum hydroxide‐coated activated carbon have reported higher sorption capacities that can be attributed to the improved interactions between fluoride and the sorbent surface charge activated by hydrogen bonding effects from the hydrogenated atmosphere (Amalraj & Pius, ; Naba Kumar, Bhaumik, & Datta, ; Prathna & Raichur, ; Wu, Chen, Ouyang, Lei, & Liu, ). However, studies on the removal of Al(III) using biochar are limited.…”

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confidence: 99%

Sequential synergetic sorption analysis of Gracilaria Rhodophyta biochar toward aluminum and fluoride: A statistical optimization approach

Babu

Reddy

Govindarajan

et al. 2020

Water Environment Research

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The present work proposes the synthesis of robust biochar from Gracilaria Rhodophyta red weeds for sequential removal of Al(III) and fluoride from wastewater. The sorption experiments have been modeled by preliminary optimization of operational parameters using 2 4 factorial statistical modeling. The model has estimated an optimum sequential synergetic removal of 44.5 mg/g of Al(III) and 2.1 mg/g of fluoride onto the biochar. FESEM, BET, XRD, EDX, and FTIR established the potentiality of biochar toward synergetic sorption of Al(III) and fluoride. The thermodynamic analysis projected that the adsorption is physisorption in nature. The adsorption of Al(III) and fluoride follows the Langmuir and Freundlich isotherm models, respectively, and the kinetic analysis established the pseudo-second-order deposition of Al(III) and fluoride ions. The synthesized adsorbent is regenerative enough and could achieve synergetic removal of Al(III) and fluoride ions from industrial-and groundwater-contaminated water bodies. © 2019 Water Environment Federation • Practitioner points• Biochar from seaweeds is explored in the sequential removal of Al(III) and F − ions. • Statistical model is developed for % adsorption and tested for reliability by ANOVA. • GRBC sorbed 44.5 and 2.1 mg/g of Al(III) and F − ions, respectively, at optimum levels. • FESEM, EDX, XRD, and FTIR characterization confirm the potentiality of the GRBC. • GRBC sorbed ⃞90% of Al(III) and F − ions from wastewater and is regenerative.

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