In the present study, response surface methodology (RSM) employing Box-Behnken design was used to optimize the parameters for biosorption of praseodymium(III) onto biowaste materials viz., crab shell (C{\textless}inf{\textgreater}R{\textless}/inf{\textgreater}S) and orange peel (OP). Various process parameters viz., pH (A: 3.0-9.0), biomass dosage (B: 0.05-0.35g/L), initial metal concentration (C: 50-350mg/L), temperature (D: 20-60°C) and contact time (E: 5-60min) were chosen for optimization. A square root transformation was suggested by the Box-Cox plot in the present case. A low p-value of {\textless}0.0001 validated the significance of the model. Maximum Pr(III) uptake of 57.8mg/g for (C{\textless}inf{\textgreater}R{\textless}/inf{\textgreater}S) and 49.9mg/g for OP was noted under optimum conditions. Among the equilibrium isotherms tested, Langmuir was found to be the best fitted model suggesting a homogeneous mode of biosorption for both the biosorbents. Kinetic studies showed better applicability of pseudo-first order model for C{\textless}inf{\textgreater}R{\textless}/inf{\textgreater}S suggesting physisorption and pseudo-second order model for OP confirming chemisorption as phenomena underlying the process. SEM analysis confirmed the homogeneous mode of biosorption. FTIR studies confirmed the involvement of amine, alcohol, ketone and amide groups in the process of Pr(III) biosorption onto C{\textless}inf{\textgreater}R{\textless}/inf{\textgreater}S and OP. Regeneration studies suggested that the biosorbents could be consistently reused upto 7 cycles with a minor metal leaching of 0.97{\%} and 0.89{\%}.

Nilanjana Mitra

Department of Bio-Medical Sciences

School of Bio Sciences and Technology

Vellore Campus

Varshini C J.S

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

Ecological Engineering

The aim of the present investigation was to study the potential of two brown seaweeds (Sargassum wightii and Turbinaria conoides) to remove praseodymium ions from solutions. Due to swelling problems, the seaweed biomasses were also immobilized using polysulfone matrices which amplified hydraulic conductivity more than 7.1 times. At optimum pH of 5, maximum Pr(III) uptakes of 131.4, 146.4, 111.2 and 119.5 mg/g were observed for free-S. wightii, free-T. conoides, polysulfone immobilized S. wightii (PISW) and polysulfone immobilized T. conoides (PITC), respectively. Experimental biosorption isotherms were successfully described using the Langmuir, Freundlich and Sips model. Owing to intraparticle diffusion, rate of Pr(III) sorption by immobilized biosorbents was slow and equilibrium attainment took 240 min compared to only 90 min by free biomasses. However, regeneration of seaweed biomasses for repeated sorption application was only possible with immobilization biosorbents. With 0.1 mol/L HCl as elutant, both PITC and PISW exhibited invariable Pr(III) uptake capacity and very high mechanical stability over 10 sorption-desorption cycles. © 2015 The Chinese Society of Rare Earths.

Journal of Rare Earths

Entrapment of brown seaweeds (Turbinaria conoides and Sargassum wightii) in polysulfone matrices for the removal of praseodymium ions from aqueous solutions

Response surface methodology (RSM) employing 5-level Box-Behnken design was used to optimize the biosorption of cerium(III) onto biowaste materials of animal and plant origin viz. prawn carapace (PC) and corn style (CS). Various process parameters viz. pH (A: 3.0-9.0), biomass dosage (B: 0.05-0.35 g/L), initial metal concentration (C: 50-350 mg/L), contact time (D: 2-6 h) and temperature (E: 20-60 °C) were chosen for optimization. A log transformation was suggested by the Box-Cox plot in the present case. A low p-value of {\textless}0.0001 validated the significance of the model. Maximum Ce(III) uptake of 218.3 mg/g for PC and 180.2 mg/g for CS was noted under optimum conditions. Among the equilibrium isotherms, Freundlich model was found to be the best fitted one suggesting a heterogeneous mode of biosorption on PC whereas Langmuir model showed the best fit suggesting homogeneous mode of cerium biosorption on CS. This was further confirmed by scanning electron microscopy (SEM). Kinetic studies showed better applicability of pseudo-first order model suggesting physisorption as phenomena underlying the process. Film-diffusion was suggested by the non-linearity of the Boyd plot. Thermodynamic studies showed that the process was endothermic and spontaneous. FTIR analysis confirmed a major involvement of the participation of amide, amines, ketones and primary alcohol groups during Ce(III) biosorption. EDAX analysis confirmed the major participation of carbon group during Ce(III) biosorption. This was the first report on parameter optimization of Ce(III) biosorption onto biowaste materials using 5-level Box-Behnken experimental design which might be helpful for the recovery of Ce(III) from aqueous environment.

Optimization of parameters for cerium(III) biosorption onto biowaste materials of animal and plant origin using 5-level Box-Behnken design: Equilibrium, kinetic, thermodynamic and regeneration 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.

Recovery of rare earth metals through biosorption: An overview

The present study was carried out using dead biomass of isolated yeast species viz. Candida rugosa and Candida laurentii as biosorbents for the removal of Zn(II) from aqueous environment. C. rugosa and C. laurentii exhibited 65.4{\%} and 54.8{\%} removal of zinc at pH 6.0 in presence of 90mgL -1 Zn(II) at 30°C in batch system. Remarkable increase in Zn(II) removal was noted using dead yeast biomass treated with anionic surfactant sodium dodecyl sulphate (SDS) which was confirmed through SEM analysis. Kinetic studies based on various models were carried out and the results showed a very good compliance with the fractional power model. The experimental data were analyzed using two, three and four parameter isotherm models. The most appropriate equation for describing the isotherm profile was Freundlich model. The biosorbent performance was evaluated in column mode packed with SDS treated dead biomass of C. rugosa entrapped in sodium alginate beads. FT-IR analysis showed the involvement of -NH, -CO and -COOH functional groups in the binding of Zn(II) by yeast. The present study confirmed that immobilized SDS treated dead biomass of C. rugosa may serve as potential and eco-friendly biosorbent for removal of Zn(II) ions from aqueous solution. {\textcopyright} 2012 Elsevier B.V.

Biochemical Engineering Journal

Kinetics and equilibrium studies on removal of zinc(II) by untreated and anionic surfactant treated dead biomass of yeast: Batch and column mode

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.

Desalination

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

The removal of Cd (II) from industrial wastewater by macrofungus Pleurotus platypus was investigated in a fixed bed column. Experiments were conducted to study the effect of important parameters such as bed depth (5-15cm) and flow rate (5-15mlmin-1). The bed depth service time model (BDST) fitted well with the experimental data and the adsorption capacity (N0) estimated from this model was 2418.12mgL-1. The effect of co-ions on adsorption of cadmium (II) was analyzed as single and multimetal systems. The breakthrough and exhaustion points were found to be earlier for biosorption of cadmium (II) in the presence of co-ions. The biosorbent was employed for the treatment of industrial effluent in a continuous column mode and its reusability was assessed. The column was regenerated by eluting cadmium (II) using 0.01M HCl and the adsorbent was reused for three sorption-desorption cycles without considerable loss in biosorption capacity. In the three cycles of biosorption, about 3.6L of industrial effluent could be treated to reach the Cd (II) standard (0.1mgL-1) established by the Central Pollution Control Board (CPCB). P. platypus proved to be the potential biosorbent for the removal of Cd (II) from industrial effluents. © 2011 Elsevier B.V.

Packed bed column studies on Cd(II) removal from industrial wastewater by macrofungus Pleurotus platypus

Optimization of parameters for praseodymium(III) biosorption onto biowaste materials using response surface methodology: Equilibrium, kinetic and regeneration studies

Journal	Data powered by TypesetEcological Engineering
Publisher	Data powered by TypesetElsevier BV
ISSN	0925-8574
Open Access	0