Encapsulation of Cyanex 302 with Alginate for Palladium Recovery

García, Esperanza Barroso; Saucedo, I.; Navarro, Ricardo García; Dzul, Mercy; González, María del Pilar Gómez; Elorza, Enrique; Guibal, Eric

doi:10.1002/masy.201600135

Cited by 5 publications

(2 citation statements)

References 35 publications

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“…In order to investigate kinetics of sorption of gold(III), platinum(IV) and palladium(II) ions on Lewatit VP OC 1026-Aliquat 336, the sorption kinetic models: pseudo-first-order (2), pseudo-second-order (3) and diffusion models as well as intra-particle diffusion model ( 4) and Dunwald-Wagner model (5) were used. Linear forms of these models are described by: ln q e À q t ð Þ ¼ lnq e À k 1 � t ðPFOÞ (2) q e = 0.8 mg/g Au(III) [25] XAD-7 impregnated by IL101 C = 0.01 M HCl, Agitation time: 7 days; q e = 87.9 mg/g Au(III) [26] XAD-1180 impregnated by IL101 C = 0.01 M HCl, Agitation time: 7 days; q e = 126 mg/g Au(III) [26] N-(diethylthiophosphoryl)-aza [18]crown-6 immobilized into Amberlite XAD-4 resin C = 0.05 M HCl q e = 42 mg/g Au(III) [27] Amberlite XAD-7 resin with a phenanthroline-derived diamide extractant N,N'diethyl-N,N'-ditolyl-2,9-diamide-1,10-phenanthroline (Et-Tol-DAPhen) C = 3 M HNO 3 q e = 74.6 mg/g Au(III) [28] XAD7HP impregnated by 2-mercaptobenzoxazole (MBO)/XAD7HP C = 0.5 M HNO 3 q e = 98.4 mg/g Pd(II) [29] Chitosan with dibenzo-18-crown-6-ether (Chitosan-DB18 C6) C o = 150 mg/L Pd(II), pH = 2 C o = 175 mg/L Pt(IV), pH = 2 q e = 17.6 mg/g Pd(II) q e = 98.4 mg/g Pt(IV) [30] Amberlite XAD7 functionalized with dibenzo-18-crown ether-6 (XAD7-DB18 C6) pH = 2, T = 298 K q e = 6.5 mg/g Pd(II) [31] Alginate-Cyanex 302 microcapsules 0.5 M HCl, T = 293 K q e = 22.1 mg/g Pd(II) [32] Monomer-impregnated adsorbent (MTCA XAD7) C o = 850 mg/L Pd(II), C = 1 M HCl q e = 7.9 mg/g Pd(II) [33] 2,2'-thiobisethanol dimethacrylate/ ethylene glycol dimethacrylate copolymer C = 4 M HCl q e = 100 mg/g Au(III) [34] Purogold™ A194 resin C = 1 M HNO 3 , T = 294 K q e = 0.76 mmol/ g Pd(II) [35] Lewatit VP OC 1026 impregnated by Aliquat 336 C = 0.1 M HCl, Agitation time: 24 h, T = 293 K, m:V = 0.1 g : 25 cm 3 q e = 94.1 mg/g Au(III) q e = 38.2 mg/g Pd(II) q e = 36.2 mg/g Pt(IV)…”

Section: Kinetic Modelsmentioning

confidence: 99%

Kinetic and Thermodynamic Studies of Precious Metals Sorption on Impregnated Lewatit VP OC 1026 from Chloride Solutions

Zinkowska,

Hubicki,

Wójcik

2024

ChemPhysChem

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Precious metals are used in many branches of industries. Due to their rarity and diminishing natural resources, more and more new methods are being sought to recover them from secondary sources, which can be electronic waste or spent car exhaust converters. This paper presents the research on the recovery of precious metals from chloride solutions using the Aliquat 336‐impregnated Lewatit VPOC 1026 sorbent. The study used a warm impregnation method without toxic solvents, which is beneficial for the environment. The maximal sorption capacities obtained for model solutions in 0.1 M HCl were: 95.6 mg/g for gold, 38.2 mg/g for palladium, and 36.2 mg/g for platinum. There were studied: kinetics and thermodynamics of adsorption, as well as amounts of the adsorbent, effects of phase contact time and HCl concentration on the adsorption of precious metals. Positive values of enthalpy change ΔH° validate that the process is endothermic. The research was also carried out on a real leaching solution obtained by digesting a spent catalytic converter, containing small amounts of platinum group metals. Desorption of precious metal ions was conducted using 1M thiourea in 1M hydrochloric acid. The obtained impregnated sorbent proved to be effective for adsorption of Au(III), Pd(II), Pt(IV) ions.

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Section: Kinetic Modelsmentioning

confidence: 99%

Kinetic and Thermodynamic Studies of Precious Metals Sorption on Impregnated Lewatit VP OC 1026 from Chloride Solutions

Zinkowska,

Hubicki,

Wójcik

2024

ChemPhysChem

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“…However, their development remains in its infancy and is often accompanied by a long recovery period and difficulty in selecting excellent strains. The wet process has become the most promising to complete enrichment and recovery of precious metals. − In the wet process, according to different mechanisms, it can be divided into adsorption, − ion exchange, complexation–extraction, and precipitation, ,− all of which are effective recovery methods. , Among them, the application of the adsorption method is gradually increasing with the advantages of fast kinetics, high enrichment coefficient, and reduced waste accumulation. In addition, the adsorption method has the advantages of simple operation, wide functionalization, and easy material availability, making it more practical and effective than other methods.…”

Section: Introductionmentioning

confidence: 99%

Highly Selective Adsorption and Recovery of Palladium from Spent Catalyst Wastewater by 1,4,7,10-Tetraazacyclododecane-Modified Mesoporous Silica

Zeng

Liu

Xiao

et al. 2022

ACS Sustainable Chem. Eng.

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A new silicon-based adsorbent with good adsorption performance on Pd(II) was synthesized from mesoporous silica as a carrier and 1,4,7,10-tetraazacyclododecane as a functional ligand. The batch method was used to investigate and evaluate the adsorption performance of the adsorbent on Pd(II) in HCl-HNO 3 solution. Influencing factors such as the contact time, pH, temperature, initial Pd(II) concentration, and elution conditions on adsorption and elution were systematically investigated and optimized. Simultaneously, adsorption kinetics, thermodynamics, and adsorption isotherms were investigated. The results revealed that under optimal adsorption conditions, the recovery rate of the adsorbent to Pd(II) could reach 98.30−99.75% in a mixed solution, which was mostly unaffected by other impurity ions. After five adsorption−desorption cycles, the recovery rate of the adsorbent to Pd(II) remained more than 93%. Pd(II) adsorption by the adsorbent was rapid within 30 min, and the recovery rate could reach 85%. In combination with density functional theory calculations, an adequate recovery mechanism was proposed to describe the selective adsorption and desorption process of Pd(II), in which the chemical adsorption dominated. As a result, this material can adsorb and recover Pd(II) with high selectivity, a rapid adsorption rate, good stability, and reusability, making it ideal for recovering waste palladium resources under acidic conditions.

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Self‐Assembling Supramolecular Hybrid Hydrogel Beads

2019

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With the goal of imposing shape and structure on supramolecular gels, we combine a low‐molecular‐weight gelator (LMWG) with the polymer gelator (PG) calcium alginate in a hybrid hydrogel. By imposing thermal and temporal control of the orthogonal gelation methods, the system either forms an extended interpenetrating network or core–shell‐structured gel beads—a rare example of a supramolecular gel formulated inside discrete gel spheres. The self‐assembled LMWG retains its unique properties within the beads, such as remediating PdII and reducing it in situ to yield catalytically active Pd0 nanoparticles. A single PdNP‐loaded gel bead can catalyse the Suzuki–Miyaura reaction, constituting a simple and easy‐to‐use reaction‐dosing form. These uniquely shaped and structured LMWG‐filled gel beads are a versatile platform technology with great potential in a range of applications.

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Encapsulation of Cyanex 302 with Alginate for Palladium Recovery

Cited by 5 publications

References 35 publications

Kinetic and Thermodynamic Studies of Precious Metals Sorption on Impregnated Lewatit VP OC 1026 from Chloride Solutions

Kinetic and Thermodynamic Studies of Precious Metals Sorption on Impregnated Lewatit VP OC 1026 from Chloride Solutions

Highly Selective Adsorption and Recovery of Palladium from Spent Catalyst Wastewater by 1,4,7,10-Tetraazacyclododecane-Modified Mesoporous Silica

Self‐Assembling Supramolecular Hybrid Hydrogel Beads

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