The present investigation attempts to recover lanthanum(III) from aqueous environments using biosorbents of animal (fish scales) and plant origin (neem saw dust). Optimization experiments were carried out using a log transformed 5-level Box-Behnken design. Maximum La(III) uptake was noted to be 200.0 mg/g in the case of fish scales (FS) and 160.2 mg/g in the case of neem sawdust (NS) under optimum conditions (pH: 6.0, biomass dosage: 0.3 g/L; 0.2 g/L, initial metal concentration: 300 mg/L; 250 mg/L, temperature: 50 °C, time: 4 h; 3 h). A low p-value of {\textless}0.0001 validated the significance of the model. The process was found to follow a homogeneous chemical mode in the case of FS whereas heterogeneity and physisorption was noted in the case of NS. This was further confirmed by scanning electron microscopy (SEM). High uptake values in the case of FS could be attributed to the involvement of both intraparticle and film diffusion. Thermodynamic studies showed that the process is endothermic and spontaneous in the case of both the adsorbents. FTIR analysis confirmed a major involvement of the participation of amide, amines, alkines, aliphatic compounds and alkyl groups during La(III) biosorption. Maximum adsorption efficiency and recovery of La(II) from ceramic industrial effluent using FS were noted as 88.5{\%} and 84.6{\%} which were obtained in column mode at a flow rate of 1 ml/min, bed height of 12 cm and 0{\%} dilution. Regeneration studies suggested that the biosorbent FS could be consistently reused up to 6 cycles. {\textcopyright} 2014 Elsevier Ltd. All rights reserved.

Nilanjana Mitra

Department of Bio-Medical Sciences

School of Bio Sciences and Technology

Vellore Campus

Das D

Jaya Sre Varshini C

Vellore Institute of Technology (VIT) is a private university located in&nbsp;Tamil Nadu, India. Founded in 1984, as Vellore Engineering College, the institution offers 20 undergraduate, 34 postgraduate, four integrated and four research programs. It has campuses in Vellore, Amravati, Bhopal and Chennai.

VIT is one of the top ranked private universities in India according to NIRF, THE and QS Rankings.&nbsp;Govt. of India has recognized&nbsp;VIT, Vellore as an&nbsp;Institution of Eminence. This has allowed VIT to take independent quality initiatives and move up in world ranking.

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VIT University

Minerals Engineering

Korean Journal of Chemical Engineering

Adsorptive removal of nickel(II) ions from aqueous environments using gum based and clay based polyaniline/chitosan nanobiocomposite beads and microspheres: Equilibrium, kinetic, thermodynamics and ex-situ studies

The current study presents a novel approach for the removal of Ni(II) from aqueous environments using plant gum-based (PG) and clay-based (CL) nanobiocomposite (NBC) composed of ZnO nanoparticles and chitosan. Parameters like pH, contact time, temperature, initial metal concentration and adsorbent dosage were optimized. Under optimized conditions, maximum removal of Ni(II) was noted as 90.1{\%} and 95.5{\%} in the case of PG-NBC and CL-NBC, respectively. Equilibrium studies suggested a homogeneous mode of adsorption. Good linearity was observed for the pseudo-first order kinetic model, suggesting a physical mode of adsorption. Thermodynamic studies showed an endothermic and spontaneous nature of adsorption. The mechanism was further elucidated using SEM, EDX, AFM and FT-IR analysis. Ex-situ studies showed a maximum Ni(II) removal of 87.34{\%} from electroplating wastewater using CL-NBC in column mode. Regeneration studies suggested that CL-NBC could be consistently reused up to 4 cycles.

Application of novel nanobiocomposites for removal of nickel(II) from aqueous environments: Equilibrium, kinetics, thermodynamics and ex-situ studies

The present study investigates the enhanced removal of total dissolved solids (TDS) from tap water in Vellore using bead and membrane form of nanobiocomposite (CNTs, gum Arabic and chitosan), previously cyclodextrinated, sulfonated and aminated. The potential of beads and membranes was individually exploited in terms of pH, dosage, dilutions and time. Among various pretreated materials, the aminated form of both bead and membrane exhibited the maximum TDS removal efficiency followed by the sulfonated and cyclodextrinated form at pH6.0, dosage value 6.0g/L and time 6h under optimum condition. The materials were characterized in terms of their BET surface area (aminated (198cm2/g){\textgreater}sulfonated (145.6cm2/g){\textgreater}cyclodextrinated (102.3cm2/g){\textgreater}control (78.0cm2/g)). Packed bed column studies were conducted at varying dosages of bead, membrane and sophorolipid and flow rates. A 3-level Box-Behnken design was used to validate the model significance. Equilibrium and kinetic studies were conducted to determine the mode of adsorption and rate of the process. To elucidate the mechanism of the process, spectroscopic analysis using SEM-EDX and FT-IR was done. Regeneration cycles were performed which showed that the novel duo could be successfully regenerated up to 10cycles/day with an effective treatment of 8L of tap water.

Desalination

Enhanced TDS removal using cyclodextrinated, sulfonated and aminated forms of bead–membrane duo nanobiocomposite via sophorolipid mediated complexation

In the present study, the biosorption potential of sulfonated plant gum-mushroom biocomposite (SfGM) for the removal of Ag(I) and Zn(II) was investigated in a single and binary system. Various parameters viz., pH, initial metal concentration, biomass dosage, contact time, temperature and gum dosage were optimized. The metal adsorption was found to reach equilibrium at 60. min. In single metal system, maximum adsorption capacity of SfGM was calculated to be 137.8. mg/g for Ag(I) and 287.9. mg/g for Zn(II) ions. In a binary system, an antagonistic nature was observed and Ag(I) uptake was found to be higher as compared to Zn(II) uptake owing to the difference in their ionic radii. Equilibrium studies suggested a heterogenous mode of adsorption. Kinetic studies suggested a chemical mode of adsorption in a binary system and a physical mode in a single system. Thermodynamic studies suggested an endothermic nature of biosorption in case of Zn(II) whereas an exothermic nature was found to be predominant in case of Ag(I) biosorption. Interaction effects were studied using extended Langmuir and SRS equations. Spectroscopic analysis viz., SEM, EDX and FT-IR studies validated the above mentioned results. Ex-situ applications were performed using electroplating wastewater in a packed bed column at varying bed heights, flow rates and dilutions. The column data was analyzed using bed depth service time (BDST) model and Thomas model. The present study highlights the potential of sulfonated form of gum-mushroom composite as cost effective adsorbent for the removal of heavy metals from aqueous environment. © 2014 Elsevier B.V.

Ecological Engineering

Removal of Ag(I) and Zn(II) ions from single and binary solution using sulfonated form of gum arabic-powdered mushroom composite hollow semispheres: Equilibrium, kinetic, thermodynamic and ex-situ studies

Rare earth metals (REMs) are a series of 17 elements that have widespread and unique applications in high technology, power generation, communications and defense industries. These resources are also pivotal to emergent sustainable energy and carbon alternative technologies. Recovery of REMs is interesting due to its high market prices along with various industrial applications. Conventional technologies, viz. precipitation, filtration, liquid-liquid extraction, solid-liquid extraction, ion exchange, super critical extraction, electrowinning, electrorefining, electroslag refining, etc., which have been developed for the recovery of REMs, are not economically attractive. Biosorption represents a biotechnological innovation as well as a cost effective excellent tool for the recovery of rare earth metals from aqueous solutions. A variety of biomaterials such as algae, fungi, bacteria, resin, activated carbon, etc., have been reported to serve as potential adsorbents for the recovery of REMs. The metal binding mechanisms, as well as the parameters influencing the uptake of rare earth metals and isotherm modeling are presented here. This article provides an overview of past achievements and current scenario of the biosorption studies carried out using some promising biosorbents which could serve as an economical means for recovering REMs. The experimental findings reported by different workers will provide insights into this research frontier. {\textcopyright} 2013 The Chinese Society of Rare Earths.

Journal of Rare Earths

Recovery of rare earth metals through biosorption: An overview

An efficient dye biosorbent was developed for the treatment of textile wastewater by entrapping dead cells of C. tropicalis, within sodium alginate matrix. The biosorbent performance was evaluated in packed bed column with different pH (3 to 6), wastewater strength (25{\%}, 50{\%} 75{\%}), bed height (5cm-15cm) and flow rate (0.5mLmin -1 to 1mLmin -1). pH 5, undiluted wastewater, bed height 15cm and flow rate 0.5mLmin -1 were found to be optimum for dye biosorption. The linearized form of the modified Thomas model equation fitted well with the experimental data and described the dynamic adsorption of synthetic dyes from textile wastewater. The Bed depth service time model was used to express the effect of bed height on breakthrough curves. Dye laden immobilised dead C. tropicalis was regenerated using 0.01molL -1 NaOH at an elutant flow rate of 1mLmin -1. The reusability of the immobilised biomass was tested in consecutive adsorption-desorption cycles. The FT-IR spectral analysis showed the involvement of amine, hydroxyl, carbonyl, amide and phosphoryl groups in biosorption of dyes from wastewater. The analysis of treated samples showed almost zero colour and a significant decrease in Total Dissolved Solids (TDS). {\textcopyright} 2011 Elsevier B.V.

Packed bed column studies for the removal of synthetic dyes from textile wastewater using immobilised dead C. tropicalis

Response surface methodology (RSM) employing the three-level Box-Behnken factorial design was used to optimize the biosorption of Ag(I) by the macrofungus Pleurotus platypus. The initial Ag(I) concentration (100-300mg/L), pH (3.0-9.0) and biomass dosage (1.0-5.0g/L) were chosen as the process variables for the optimization. A coefficient of determination (R2) value (0.99), model F value (234.18) and its low p-value (F{\textless}0.0001) along with the lower value of coefficient of variation (2.44{\%}) indicated the fitness of response surface quadratic model during the present study. At the optimum pH (6.0), initial metal concentration (220mg/L) and biomass dosage (3.0g/L), the model predicted 46.7mg/g Ag(I) uptake and an experimental 46.77mg/g Ag(I) uptake by P. platypus was obtained. This is the first report on Ag(I) sorption by P. platypus using statistical experimental design employing RSM which may be helpful towards the treatment of industrial effluent containing silver. The present study has confirmed the effectiveness of the macrofungus Pleurotus platypus as biosorbent of Ag(I) and thus, P. platypus can be exploited for the removal of silver from industrial effluents before their discharge into water bodies. {\textcopyright} 2011 WILEY-VCH Verlag GmbH {\&amp;} Co. KGaA, Weinheim.

CLEAN - Soil, Air, Water

Response Surface Approach for the Bisorption of Ag(I) by MacrofungusPleurotus platypus

The removal of Cr (VI) from tannery wastewater by neem sawdust was investigated in a fixed bed column. The experiments were conducted to study the effect of important parameters such as bed depth (5-15 cm) and flow rate (5-15 ml min-1). The bed depth service time model (BDST) fit well with the experimental data. The adsorption capacity estimated from the BDST model was 33,009.9 mg g-1. The column was regenerated by eluting chromium (VI) using 2 N NaOH after adsorption studies. The desorption of Cr (VI) failed to reach 100{\%} in each cycle because some amount of adsorbed Cr (VI) got reduced to Cr (III) in the biosorbent surface and released into the aqueous phase. The effect of co-ions on adsorption of Cr (VI) was studied in column mode, where the breakthrough and the exhaustion time of the column decreased in the presence of co-ions. In the three cycles of biosorption, about 3.75 L of tannery effluent were treated to reach the chromium (VI) standard (0.1 mg L-1) established by the Central Pollution Control Board (CPCB). Neem sawdust proved to be the potential biosorbent for the removal of Cr (VI) from tannery effluents. {\textcopyright} 2010 Elsevier B.V.

Journal	Data powered by TypesetMinerals Engineering
Publisher	Data powered by TypesetElsevier BV
ISSN	0892-6875
Open Access	0