Biosorption and desorption of lanthanum(III) and neodymium(III) in fixed‐bed columns with <i>Sargassum</i> sp.: Perspectives for separation of rare earth metals

Oliveira, Roberto Carlos de; Guibal, Eric; Garcia, Oswaldo

doi:10.1002/btpr.1525

Cited by 41 publications

(25 citation statements)

References 33 publications

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“…The extraction of metals from these leachates or waste streams can be processed by precipitation (Rabatho et al 2013), solvent extraction (Abreu and Morais 2014;Tunsu et al 2014;Vander Hoogerstraete and Binnemans 2014;Xie et al 2014), ion exchange and chelating resins (Abdel-Rahman Adel et al 2010; Barron et al 2008;Lokshin et al 2013;Xiong and Zheng 2010), extractant-impregnated resins (Lee et al 2010) and biosorption (Das and Das 2013;Hosomomi et al 2013;Oliveira et al 2012Oliveira et al , 2011Wu et al 2011). The selection of the appropriate process depends on the composition of the effluents (i.e., metal concentration, metal speciation, presence of competitor ions) and may face some critical problems: the production of huge amounts of contaminated sludge, difficulty to reach target discharge levels (precipitation) and economic limitations (poor competiveness of solvent extraction at low metal concentration; cost of sophisticated resins).…”

Section: Introductionmentioning

confidence: 99%

Diethylenetriamine-functionalized chitosan magnetic nano-based particles for the sorption of rare earth metal ions [Nd(III), Dy(III) and Yb(III)]

et al. 2015

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The recovery of three rare earth (RE) metals ions [Yb(III), Dy(III) and Nd(III), belonging to heavy, mild and light REs, respectively] was investigated using hybrid chitosan-magnetic nano-based particles functionalized by diethylenetriamine (DETA). The effect of pH on sorption performance was analyzed: the optimum initial pH value was found close to 5 (equilibrium pH value close to 6.5). The nanometric size of sorbent particles (30-50 nm) minimized the contribution of resistance to intraparticle diffusion on the control of uptake kinetics, which is efficiently modeled using the pseudo-second order rate equation: under selected experimental conditions the contact time required for reaching equilibrium was less than 1 h. Sorption isotherms were efficiently modeled using the Langmuir equation: maximum sorption capacities reached about 50 mg metal g -1 , regardless of the RE. The temperature had a very limited effect on sorption capacity (in the range 300-320 K). The thermodynamic parameters were determined: the sorption was endothermic (positive values of DH°), spontaneous (negative values of DG°) and contributed to increasing the disorder of the system (positive values of DS°). The three REs have similar sorption properties on DETA-functionalized chitosan magnetic nano-based particles: the selective separation of these elements seems to be difficult. The sorbed metal ions can be removed from loaded sorbents using thiourea, and the sorbent can be recycled for at least five sorption/desorption cycles with a limited loss in sorption performance (by less than 6 %). The saturation magnetization was close to 20 emu g -1 ; this means that nano-based superparamagnetic particles can be readily recovered by an external magnetic field, making the processing of these materials easy.

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Section: Introductionmentioning

confidence: 99%

Diethylenetriamine-functionalized chitosan magnetic nano-based particles for the sorption of rare earth metal ions [Nd(III), Dy(III) and Yb(III)]

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“…Entretanto, os valores calculados para este parâmetro são muito similares de maneira que os mesmos não são suficientes para inferir tal informação. No caso da biossorção de La e Nd pela macroalga Sargassum sp., os valores de K L obtidos foram maiores para La (505,11 L/g) em comparação com Nd (481,80 L/g), demonstrando a preferência da alga marrom pela adsorção de TRs leves (Oliveira et al, 2012).…”

Section: Resultsunclassified

Avaliação Do Uso De Biomassa Bacteriana Imobilizada Na Biossorção De Terras-Raras Leves E Médias

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A busca por fontes alternativas de recuperação e separação dos elementos puros de terras--raras (TRs) é vista como uma ação prioritária e estratégica por diversos países demandantes desses elementos. Em alternativa aos processos clássicos de extração de TRs, o processo de biossorção vem sendo avaliado, em uma combinação da biotecnologia e metalurgia extrativa. Sendo assim, o presente trabalho buscou avaliar a capacidade da biomassa imobilizada da bactéria Bacillussubtilis na biossorção de lantânio (TR leve) e samário (TR médio), visando seu uso na separação desses elementos. As maiores porcentagens de biossorção de lantânio (La) e samário (Sm) em sistemas mono--elementares corresponderam à 94,4% e 94,9%, respectivamente, a partir de concentrações iguais (C i ) à 15 mg/L. Em soluções com C i = 100 mg/L, 89,3% de La e 91,9% de Sm foram biossorvidos. O mesmo comportamento pode ser observado para a solução bi--elementar La+Sm, onde 79,9% de La e 88,8% de Sm foram biossorvidos em soluções com C i = 15 mg/L, e, 69,4% de La e 83,4% de Sm foram biossorvidos em C i =100 mg/L. A aplicação dos dados obtidos aos modelos de adsorção de Langmuir e Freundlich demonstrou que as isotermas de adsorção obtidas para La e Sm em ambos os sistemas avaliados foram satisfatórias para ambos os modelos, sugerindo a ocorrência da biossorção em monocamada assim como condições heterogêneas na superfície, onde ambas condições podem co--existir sob as condições experimentais testadas. PALAVRAS--CHAVE:Bacillussubtilis, imobilização celular, alginato de cálcio, biossorção, terras--raras EVALUATION OF THE USE OF BACTERIAL IMMOBILIZED BIOMASS IN LIGHT AND MEDIUM RARE--EARTH ELEMENTS BIOSORPTION ABSTRACTThe search for alternative sources of recovery and separation of pure rare earth elements (REE) is a priority and strategic action by several countries demanding these elements. As an alternative to classical processes of extraction of REE, the biosorption process has been evaluated in a combination between biotechnology and extractive metallurgy. Therefore, the present work aimed to evaluate the capacity of immobilized biomass of Bacillus subtilis to the biosorption of lanthanum (light REE) and samarium (medium REE), aiming its use in the separation of these elements. The highest percentages of lanthanum (La) and samarium (Sm) biosorption in single--element systems corresponded to 94.4% and 94.9%, respectively, from an initial concentration ( i C) of 15 mg/L. In solutions with i C= 100 mg/L, 89.3% of La and 91.9% of Sm were biosorbed. The same behavior can be observed for the bi--elemental solution La + Sm, where 79.9% of La and 88.8% of Sm were biosorbed in solutions of i C= 15 mg/L, and 69.4% of La and 83.4% of Sm were biosorbed in i C= 100 mg/L. The application of the data obtained to the adsorption models of Langmuir and Freundlich showed that the adsorption isotherms obtained for La and Sm in both systems were satisfactory for both models, suggesting the occurrence of monolayer biosorption as well as heterogeneous surface conditions, where bot...

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“…However, these waste streams can also contain valuable metals such as platinumgroup metals [5,6], silver, gold [7], gallium, indium, rareearth elements (REEs) [8][9][10][11][12], or uranium [13,14]. The recovery of valuable metals from dilute aqueous waste streams processing from acid mine drainage, coal mines [15], from industrial effluents, or from treatment of spent materials (wastes and end-of-life consumer goods) comes like complementary to primary mining resources [14,16,17].…”

Section: Introductionmentioning

confidence: 99%

Dy(III) recovery from dilute solutions using magnetic-chitosan nano-based particles grafted with amino acids

et al. 2015

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Magnetic-chitosan nano-based particles were successfully prepared by a simple one-pot co-precipitation method before being functionalized with three different amino acid groups (i.e., alanine, serine, and cysteine) using epichlorohydrin as the linking agent. The structural and functional characteristics of the nanosorbents were investigated by elemental analysis, Fourier transform infrared spectrometer, X-ray diffraction, TEM, and vibrating sample magnetometry. The sorption properties of these materials were tested for Dy(III) recovery from aqueous solution: pH effect, uptake kinetics, and sorption isotherms were investigated. Sorbent particles are super-paramagnetic and their size is in the range of 15-40 nm. Kinetic profiles are successfully modeled with the pseudo secondorder rate equation. The Langmuir and the Dubinin-Radushkevich equations fit well-sorption isotherms. The maximum sorption capacities at pH 5 (optimum pH, and at T: 27 ± 1°C) are close to 14.8, 8.9, and 17.6 mg Dy g -1 for alanine, serine, and cysteine type, respectively. Cationic species RE(III) in aqueous solution appear to be sorbed by combined chelation and anion-exchange mechanisms. The sorption process begins at low-metal concentration by a physical monolayer sorption at low ion concentration before metal ions can be sorbed at higher metal concentration by coordination. The values of the thermodynamic parameters DG°and DH°indicate the spontaneous and endothermic nature of the mechanism, while the positive values of DS°show that during the sorption process the randomness increases. Finally, the sorbent can be efficiently regenerated using acidified thiourea: the amount of Dy(III) sorbed is hardly reduced, at least during the first four sorption/desorption cycles.

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Biosorption and desorption of lanthanum(III) and neodymium(III) in fixed‐bed columns with Sargassum sp.: Perspectives for separation of rare earth metals

Cited by 41 publications

References 33 publications

Diethylenetriamine-functionalized chitosan magnetic nano-based particles for the sorption of rare earth metal ions [Nd(III), Dy(III) and Yb(III)]

Diethylenetriamine-functionalized chitosan magnetic nano-based particles for the sorption of rare earth metal ions [Nd(III), Dy(III) and Yb(III)]

Avaliação Do Uso De Biomassa Bacteriana Imobilizada Na Biossorção De Terras-Raras Leves E Médias

Dy(III) recovery from dilute solutions using magnetic-chitosan nano-based particles grafted with amino acids

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