A selective sorbent for concentrating noble metals

New chelating sorbents have been synthesized by aminating chloromethylated styrenedivinylbenzene macroporous copolymers with 3(5)-methylpyrazole. The sorption of noble metals from acid solutions and the selectivity has been studied. The sorbents are of interest for selective concentration and extraction of the noble metals.     

Sorption preconcentration in combined methods for the determination of noble metals

Combined methods for the determination of noble metals with the use of sorption preconcentration with complexing, anion-exchange, and other sorbents are reviewed. Characteristics of sorbents, techniques of sorption preconcentration, and techniques for the preparation of a concentrate for determination are considered. Features of instrumental methods for the determination of noble metals in the analysis of different materials are discussed. Examples of the use of sorption preconcentration in combined methods for the determination of noble metals are given from publications between 1996–2005.     

Accurate determination of the noble metals II. Determination methods

As was shown in the first part of this contribution, accurate analytical determination of the noble metals in rocks, ores and alloys needs a sophisticated sample pretreatment prior to the final determination step of the preconcentrated elements. For this many instrumental and classical methods are available, the choice of which is usually dictated by levels of precious metal to be handled, nature of sample matrix and availability of the instruments. For trace levels (μg/g range) flame atomic absorption and inductively coupled plasma (ICP) emission spectrometry can be used. ICP emission is favoured because of ease of multi-element operation. At the sub-μg/g level furnace atomic absorption and nuclear techniques (mainly neutron activation) are favoured. Minor and % concentrations are best handled by X-ray fluorescence. The use of standard reference samples and internal and external laboratory control schemes are essential to the accurate determination of precious metals.     

Atomic-absorption spectroscopic determination of noble metals

Zusammenfassung Die AAS-Bestimmung von Platin wird von zahlreichen Elementen zum Teil sehr stark gestört. Durch Zusatz von Uran kann der Einfluß von Palladium und Rhodium mit Hilfe quadratischer Korrekturgleichungen beseitigt werden. Lanthan ist als Puffer ungeeignet.Teil 3: diese Z.280, 359 (1976)     

Accurate determination of the noble metals I. Sample decomposition and methods of separation

This is the first of two papers to demonstrate the present status of the sophisticated analytical chemistry of the precious metals. In the present paper the methods of sample pretreatment will be surveyed. The determination methods will be covered in the next issue.     

New chelating sorbents for noble metals

The properties of the new ehelate-forming “POLYORGS” sorbents for concentration of noble metals are discussed. POLYORGS are made from different polymeric matrices (polystyrene, copolymers of styréne with divinylbenzene, fibrous materials). They contain heterocyclic amine and amidoxime groups, and are selective for noble metals. Some methods of noble metal determination after preliminary concentration of POLYORGS sorbents are given.     

Determination of noble metals by neutron-activation analysis

The scope and limitations of neutron-activation analysis in the field of the platinum metals are discussed. Special attention is given to interferences that occur in determination of noble metals in platinum metals and in natural samples. The problem of standards, carriers and chemical yield determination is emphasised. A recommendation is given of modern techniques for counting radionuclides formed by neutron activation of the platinum metals.     

The extraction of noble metals with n-octylaniline

The extraction of noble metals with n-octylaniline at varying concentrations of different mineral acids was studied, and optimum conditions for their separation from the base metals commonly present in platinum-bearing materials were established. The successful application of the procedure to the analysis of mattes, sludges, and flotation concentrates is shown. The lower limit of determination in such materials is 100 ppm for Pt and Ir, 40 ppm for Ru, and 10 ppm for Pd and Rh.     

A critical review of neutron activation and tracer methods for the determination of the noble metals

Neutron activation methods for the seven noble metals are critically reviewed up to December, 1965. The methods deal with the determination of trace impurities in each noble metal as well as traces of noble metals in media such as organic material, fission product and other solutions, ores, alloys, minerals, silica and base metals. The need for confirmatory evidence in the case of such complex materials as ores is emphasized.     

New solid extractants for preconcentrating noble metals

New solid extractants are synthesized with the use of imidazolium and phosphonium ionic liquids for preconcentrating noble metals. Ionic liquids are selected and conditions for their immobilization on various solid matrices are found. The adsorption properties of the synthesized solid extractants for platinum(IV) in hydrochloric acid solutions are studied. The solid extractants obtained by binding 1-hexadecyl-3-methylimidazolium bromide and trihexyltetradecylphosphonium chloride to polymeric matrices and multiwall carbon nanotubes possess good kinetic properties and selectivity in 1 M HCl, and can be used to preconcentrate Pt(IV), Pd(II), and Au(III) in combined methods of their determination.     

Hollow and cage-bell structured nanomaterials of noble metals

Mastery of the structure of nanomaterials enables control of their properties to enhance their performance for a given application. Herein we demonstrate the synthesis of metal nanomaterials with hollow interiors or cage-bell structures based on the inside-out diffusion of Ag in core-shell structured nanoparticles. It begins with the synthesis of core-shell Ag-M or core-shell-shell M(A)-Ag-M(B) nanoparticles in an organic solvent. Ag is then extracted from the core or the inner shell by bis(p-sulfonatophenyl)phenylphosphane, which binds strongly with Ag(I)/Ag(0) to allow the complete removal of Ag in 24-48 h, leaving behind an organosol of hollow or cage-bell structured metal nanomaterials. Because of their relatively lower densities, which usually translate to a higher surface area than their solid counterparts, the hollow and cage-bell structured metal nanomaterials are especially relevant to catalysis. For example, cage-bell structured Pt-Ru nanoparticles were found to display outstanding methanol tolerance for the cathode reaction of direct methanol fuel cells (DMFCs) as a result of the differential diffusion of methanol and oxygen in the cage-bell structure.     

Neutron activation analysis of noble metals in vegetation

Detection limits are presented for the platinum metals in vegetation for different neutron activation analysis conditions, namely, short irradiation, cyclic and long irradiations both thermally and epithermally. These detection limits for instrumental neutron activation analysis are compared with those using preconcentration technique—dry ashing and fire assay and post irradiation separation of the platinum metals using Srafion NMRR in exchange resin. The results are evaluated for plant material and it is concluded that dry ashing followed by cyclic, epithermal irradiation for rhodium and palladium and long, thermal irradiations for osmium, platinum, iridium and ruthenium enable these elements to be detected in plants at background levels.     

Separation of noble metals by circular thin-layer chromatography

Summary A method has been described for the separation and identification of noble metals by circular thin-layer chromatography. The method is simple and convenient and separation is complete within 2 min. Best results have been obtained on alumina layers with acetone/aoetylacetone/2 M hydrochloric acid (100103) as solvent mixture. Reagents used for detection were rubeanic acid, thiourea, and stannous chloride. The following elements could be detected with sensitivities ranging from 0.1 g to 3.0 g: Rh, Ru, Pt, Au, Os, Pd, Ir, and Cu. Interferences are caused by Ni, Go, Mn, and Fe, yet it is possible to distinguish these from the noble metals on separate chromatograms.

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Zusammenfassung Zur Trennung und Identifizierung von Edelmetallen wird das Verfahren der Zirktdar-Dünnschichtchromatographie empfohlen. Die Methode ist einfach durchzuführen und erfordert nur 2 min für eine vollständige Trennung. Am besten hat sich ein Lösungsmittel aus Aceton, Acetylaceton und 2 m Salzsäure (100103) und Aluminiumoxid als Dünnschichtmaterial bewährt. Als Nachweisreagentien werden Rubeanwasserstoff, Thioharnstoff und Zinn(II)-chlorid verwendet. Folgende Elemente wurden mit Empfindlichkeiten zwischen 0,1 und 3,0 g erfaßt: Rh, Ru, Pt, Au, Os, Pd, Ir und Cu. Störungen wurden durch Ni, Co, Mn und Fe verursacht, jedoch können diese von den Edelmetallen auf getrennten Chromatogrammen unterschieden werden.

     

Carbon adsorbents for the sorpting and concentrating nobel metals

Kinetic, sorption and selectivity properties of commercial adsorbents are improved by adding petroleum residues (tar asphaltene concentrates) 13% of whole mass. Obtained adsorbents can be used for selective extraction of nobel metals from multicomponent polymetallic solutions of heavy metals and fro sewages purification for removing arsenic.     

Analytical techniques for corrosion studies on noble metals

The suitability of various analytical methods for studying the corrosion of gold, silver and palladium in various electrolytes has been investigated. The methods included potentiometry with ion-selective electrodes, polarography and atomic-absorption spectrophotometry. All three methods are useful for monitoring low corrosion rates by solution analysis but each has its limitations. Concentrations in the ng/ml range can be measured routinely with errors of 10% or less.     

Solvent extraction of noble metals with derivatives of thiourea

Studies on the use of diphenylthiourea, hexamethylene-N'-phenylthiourea, N,N-hexa-methylene-N'-isohexylthiourea and di-tert-butylthiourea for the extraction and group concentration of noble metals are reported. A preliminary treatment of solutions of the platinum metals with tin(II) chloride is useful in accelerating the reactions. The chemistry of the extraction and the properties of the extracted compounds are discussed. Hexamethylene-N'-phenylthiourea provides the best selectivity in the presence of copper, whereas the isohexylthiourea derivative provides the greatest solubility.