Liquid-liquid extraction study of tellurium(IV) with N-n-octylaniline in halide medium and its separation from real samples

N-n-Octylaniline in xylene is used for extractive separation of tellurium(IV) from hydrochloric acid media. Tellurium(IV) is extracted quantitatively with the 3% reagent in xylene from 5.5 to 7.5 M hydrochloric acid. It is stripped from organic phase with 1:1 ammonia and estimated spectrophotometrically with pyrimidine-2-thiol (4'-bromoPTPT). The effects of metal ion, acids, reagent concentration, diluents and various foreign ions have been investigated. The log-log plots of distribution ratio (D(Te(IV))) versus N-n-octylaniline concentration indicate that the nature of extracted species is [(RR'NH(2)(+))(2) TeCl(6)(2-)](org). The method affords binary separation of tellurium(IV) from gold(III), selenium(IV), bismuth(III), copper(II), lead(II), antimony(III), germanium(IV) and is applicable to the analyses of synthetic mixture containing associated metal ions and alloy samples. The method is simple, selective, rapid and accurate.     

Fabrics and papers modified with analytical reagents for the test determination of selenium(IV) and tellurium(IV)

It is shown that Malachite Green and Crystal Violet immobilized on viscose fabrics can be used as reagents for the rapid determination of selenium(IV) and tellurium(IV). Selenium is determine by the color intensity of ion associates formed by the reagents with the triiodide ion formed upon the reduction of selenium(IV) with potassium iodide and tellurium, by the color intensity of reagent ion associates with telluromolybdic heteropoly acid. The analytical ranges for selenium and tellurium(IV) were 0.005–0.5 and 0.01–0.1 mg/L upon passing 20 and 100 mL of a test solution through the indicator matrix, respectively. The duration of analysis does not exceed 15–20 min. The relative standard deviation is 50%. Test strips were proposed for determining 0.1–100 mg/L selenium(IV) and 1–1000 mg/L tellurium(IV) by the length of the colored zone. The determination of selenium(IV) is based on the oxidation of 4-nitrophenylgydrazine to its diazonium salt and salt interaction with naphthylamine chemically immobilized on paper with the formation of a red azo compound. The determination of tellurium(IV) is based on its reaction with Bismuthol II immobilized on a paper.     

Determination of selenium(IV) and other forms of selenium dissolved in sea water by anion-exchange resin loaded with sulfonic acid derivative of bismuthiol-II and hydride generation atomic-absorption spectrometry

Summary A sulfonic acid derivative of bismuthiol-II (bisIIS) was synthesized from 4-hydrazinobenzene sulfonic acid and carbon disulfide. Selenium(IV) was adsorbed selectively and quantitatively on the anion-exchange resin loaded with bis-IIS. Selenium adsorbed on the resin was eluted by the use of penicillamine and determined by hydride generation atomic absorption spectrometry (hydride generation/AAS). Selenium(VI) and other forms of selenium, which were not adsorbed onto the resin, were collected on the resin after digestion with nitric acid followed by reduction with hydrochloric acid. Separative preconcentration of selenium(IV), selenium(VI) and other forms of selenium in 0.5 mol/l sodium chloride could be carried out successfully by the proposed procedures. However, in the case of estuarial sea water containing a large quantity of organic substances, selenium(IV) could not be separated, because organic substances interfered with the reduction of selenium(VI) to selenium(IV) by the use of hydrochloric acid. Selenium(IV) and total amount of selenium(VI) and other forms of selenium dissolved in polluted sea water samples were determined by the proposed procedures.

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Bestimmung von Selen (IV) und anderen in Meereswasser gelösten Selenformen mit Hilfe eines mit dem Sulfonsäurederivat von Bismuthiol-II beladenen Anionenaustauschers und der Hydrid-AAS

     

Selective collection of selenium(IV) on anion-exchange resin with azothiopyrine disulphonic acid

Azothiopyrine disulphonic acid (ATPS) has been shown to be terfunctional, namely it can form a selenotrisulphide by reaction of its thiol group with selenium(IV), bind to an anion-exchange resin by ion-exchange through its sulphonate group, and be strongly physically adsorbed on the ion-exchange resin, ATPS adsorbed on the resin does not bleed into solution even in the presence of sodium chloride and hydrochloric acid. The collection of seleniurn(IV) is practically complete when ATPS is added to a selenium(IV) solution and the reaction product is collected on the anion-exchange resin. Selenium(IV) is not satisfactorily collected, however, by reaction with anion-exchange resin loaded with ATPS. The sorbed selenium can be eluted [as Se(IV)] with 13M nitric acid and directly determined fluorometrically in the eluate.     

Determination of selenium(IV) and tellurium(IV) by differential pulse polarography

Differential pulse polarographic methods for the determination of selenium(IV) and tellurium(IV) in nitric acid medium are described. The peak current is maximal when 0.25M nitric acid medium is used, the DPP peaks for Se(IV) and Te(IV) being at -0.54 and -0.8 V vs. Ag/AgCl respectively. The peak current is a linear function of selenium concentration over three ranges, 5.1 x 10(-6)-1.3 x 10(-5), 1.27 x 10(-5)-1.27 x 10(-4) and 1.27 x 10(-4)-7.60 x 10(-4)M Se(IV), with different slopes. The plot for Te(IV) is linear over the range 0.78 x 10(-6)-9.40 x 10(-5)M.     

Extraction and separation studies of tellurium(IV) with tris-(2-ethyl hexyl) phosphate

A method is proposed for the extraction of microgram levels of tellurium(IV) from halide media with tris-(2-ethyl hexyl) phosphate dissolved in toluene as extractant. The optimum conditions have been evaluated from a critical study of acid concentration, extractant concentration, period of equilibration and effect of solvent. Tellurium ion from the organic phase is stripped with water and determined spectrophotometrically with stannous chloride. The method affords binary separation of tellurium from copper, bismuth, gold and selenium and is applicable to the analysis of alloy samples and synthetic mixtures. The method is fast, accurate and precise.     

Solvent extraction separation of tin (IV) with 2-ethylhexyl phosphonic acid mono-2-ethylhexyl ester (PC-88A)

Solvent extraction of tin(IV) from hydrochloric acid media was carried out with 2-ethylhexyl phosphonic acid mono-2-ethylhexyl ester (PC-88A) in toluene. Tin(IV) was quantitatively extracted with 2.5x10(-2) M PC-88A in toluene from 0.1-0.3 M HCl when equilibrated for 5 min. Tin(IV) from the organic phase was stripped with 4 M HCl and determined spectrophotometrically by both the morin and pyrocatechol violet method. The nature of the extracted species was determined from the log-log plots. Various other diluents such as xylene, hexane and cyclohexane also gave quantitative extraction of tin. The metal loading capacity of the reagent was found to be 0-15 ppm of tin(IV). The extraction of tin(IV) was carried out in the presence of various ions to ascertain the tolerance limit of individual ions. Tin(IV) was successfully separated from commonly associated metal ions such as antimony(III), bismuth(III), lead(II), thallium(I), copper(II), nickel(II), etc. The method was extended for determination of tin in real samples.     

The separation of tellurium and selenium by polyurethane foam sorbents

Tellurium and selenium can be sorbed from hydrochloric acid and hydrobromic acid solution by both polyether and polyester-based polyurethane foam. Although some acid is needed, the substitution of sodium chloride or sodium bromide increases the extraction significantly. Tellurium is extracted rapidly with > 99% sorbed in 2 min from 1.0/5.0M and 2.0/4.0M hydrochloric acid/sodium bromide. Selenium can also be sorbed quantitatively but much more slowly so that a separation is possible based on the relative rates of extraction. The capacity of polyether foam is 3% by weight of tellurium.     

Extraction and separation studies of platinum(IV) with N-n-octylaniline

N-n-octylaniline in xylene is used for the extractive separation of platinum(IV) from acidic media. Platinum(IV) was extracted quantitatively with 10 ml of 3% reagent in xylene from 0.5 to 10 and 2.5 to 10 M hydrochloric and sulphuric acid, respectively. It was stripped from organic phase with water and estimated photometrically with stannous chloride. The effect of metal ion, acids, reagent concentration and of various foreign ions has been investigated. The method affords binary separation of platinum(IV) from iron(III), cobalt(II), nickel(II) and copper(II), and is applicable to the analysis of synthetic mixtures and alloys. The method is fast, accurate and precise.     

The rate of reduction of selenium(VI) to selenium(IV) in hydrochloric acid

The reduction of selenium(VI) to selenium(IV) in 4, 5 and 6M hydrochloric acid was studied at temperatures between 50 and 95 degrees . The reaction rate was determined by measurement of the selenium(IV) formed, by continuous-flow hydride-generation atomic-absorption spectrometry. The most notable feature of the reaction is the strong increase in rate with increasing hydrogen-ion concentration and temperature. The rate increases initially with chloride concentration at constant acidity (mixtures of hydrochloric and perchloric acid) but levels off to an almost constant value at high chloride concentrations.     

Determination of very low/levels of selenium(IV) in sea water by differential-pulse cathodic stripping voltammetry after extraction of the 3,3′-diaminobenzidine piazselenol

Selenium(IV) is determined by cathodic stripping voltammetry after the formation of a piazselenol with 3,3′-diaminobenzidine. The selenium is then accumulated as HgSe on a mercury electrode by deposition at ?0.45 V. The differential-pulse cathodic stripping peak allows a detection limit of 0.01 μg l^?1. For the determination of selenium in natural waters, interferences can be avoided by extraction of the piazselenol into toluene followed by a back-extraction into 0.5 M hydrochloric acid. The accuracy of the overall procedure was checked by analyses of a standard reference material. The method was applied to the determination of selenium(IV) in sea-water samples at levels as low as 20 ng l^?1 with a concentration factor of 10 during the extraction procedure.     

Solvent extraction of tellurium (IV) with mesityl oxide. Direct nephelometric determination

Summary A fast and selective method has been developed for the extraction of tellurium(IV) with mesityl oxide. Tellurium(IV) is quantitatively extracted by pure mesityl oxide from 2.5–3M hydrochloric acid solutions. After stripping with water, it is determined nephelometrically as the bluish sol. The extracted species probably has the composition TeCl₄ · 2MeO. The optimum period of equilibration is 30 seconds. Tellurium can be extracted and determined in the presence of a large excess of selenium, silver, bismuth, lead, copper and nickel which are associated with it in minerals.

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Zusammenfassung Ein schnelles und selektives Verfahren zur Extraktion von Tellur(IV) mit Mesityloxid wurde ausgearbeitet. Aus 2,5- bis 3-m Salzsäure gelingt diese Extraktion quantitativ. Nach Waschen mit Wasser wird das bläuliche Sol nephelometriert. Die extrahierte Substanz hat vermutlich die Zusammensetzung TeCl₄ · 2MeO. Die Gleichgewichtseinstellung erfolgt in 30 sec. Tellur kann so in Gegenwart eines großen Überschusses von Se, Ag, Bi, Pb, Cu und Ni bestimmt werden, mit denen es in Mineralen vergesellschaftet ist.

     

Anion-exchange resin modified with bismuthiol-II, as a new functional resin for the selective collection of selenium(IV)

A functional resin for the collection of selenium(IV) has been prepared simply by the conversion of a common ion-exchange resin with bismuthiol-II which has three functional properties, namely the capabilities of selective reaction with selenium(IV), ion-exchange reaction with ion-exchange resin and strong physical sorption to the ion-exchange resin matrix. The binding ratio of selenium(IV) to bismuthiol-II on the resin was confirmed to be 1:4. The reaction was represented as follows: 4RSH + H(2)SeO(3)--> R-S-Se-S-R + R-S-S-R + 3H(2)O. Highly selective sorption of selenium(IV) was achieved, based on the formation of stable selenotrisulphide on the resin. Selenium(IV) sorbed on bismuthiol-II resin was eluted effectively with 8-13M nitric acid or some thiols, such as cysteine and penicillamine. In the cases of thiols, the elution of selenium was found to be also based on the formation of selenotrisulphide, and the bismuthiol-II resin was regenerated. Satisfactory results were obtained when this resin was applied to the determination of selenium(IV) in river, estuarine or sea water samples.     

Reversed-phase extraction chromatography of Germanium(IV) with tributyl phosphate on silica gel

Germanium(IV) can be separated by reversed-phase extraction chromatography with TBP as stationary phase on a column of silica gel, with 6M hydrochloric acid as the mobile phase, and stripped with various eluents. Germanium can thus be separated (by selective extraction) from those elements which are not extractable with TBP, and (by selective stripping) from elements that are extractable.     

Separation of niobium and tantalum by extraction chromatography with bis(2-ethylhexyl)phosphoric acid

A novel method is developed for the reversed-phase extractive chromatographic separation of niobium and tantalum with bis(2-ethylhexyl)phosphoric acid. Niobium is extracted from 1-10M hydrochloric acid and can be stripped with 3M sulphuric acid containing 2% hydrogen peroxide. Tantalum is extracted from 0.1-2M hydrochloric acid and can be stripped with 0.1M hydrochloric acid containing 2M tartaric acid. It is possible to separate niobium and tantalum, in different ratios, from multicomponent mixtures.     

Development of reliable analytical method for extraction and separation of thorium(IV) by Cyanex 272 in kerosene

A simple and selective spectrophotometric method has been developed for the extraction and separation of thorium(IV) from sodium salicylate media using Cyanex 272 in kerosene. Thorium(IV) was quantitatively extracted by 5 × 10⁻⁴ M Cyanex 272 in kerosene from 1 × 10⁻⁵M sodium salicylate medium. The extracted thorium(IV) was stripped out quantitatively from the organic phase with 4.0 M hydrochloric acid and determined spectrophotometrically with arsenazo(III) at 620 nm. The effect of concentrations of sodium salicylate, extractant, diluents, metal ion and strippants has been studied. Separation of thorium(IV) from other elements was achieved from binary as well as multicomponent mixtures such as uranium(VI), strontium(II), rubidium(I), cesium(I), potassium(I), Sodium(I), lithium(I), lead(II), barium(II), beryllium(II) etc. Using this method separation and determination of thorium(IV) in geological and real samples has been carried out. The method is simple, rapid and selective with good reproducibility (approximately ±2%).     

Extraktionsmethode zur Trennung kleiner Tellurmengen von Begleitelementen

Zusammenfassung Zur Trennung von Tellur aus Lösungen mit komplizierter Zusammensetzung wurde eine kombinierte Extraktionsmethode entwickelt. Die Extraktion von Eisen(III), Arsen(V), Antimon(V), Gold(III), Thallium(III), Wismut(III), Zinn(IV) und Selen(IV) erfolgt mit Diisopropyläther aus 8 M Salzsäure, wobei das gesamte Te(IV) in der wäßrigen Phase verbleibt. Diese wird dann mit Methylisobutylketon aus 4 M Salzsäure extrahiert, während in der wäßrigen Phase Kupfer(II), Aluminium(III), Silber(I), Nickel (II), Kobalt(II), Zink(II), Cadmium(II) und Blei(II) verbleiben. Die vollständige Abtrennung der Begleitelemente des Tellurs erfolgt durch zusätzliche Extraktion ihrer Kupferronate mit Methylisobutylketon bei pH 3–5. Das vorgeschlagene Extraktionsverfahren kann mit jeder bekannten Methode zur Bestimmung geringer Tellurmengen kombiniert werden.

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Extraction method for the separation of small quantities of tellurium from accompanying elements

A new combined solvent extraction method is proposed for the separation of tellurium from solutions of complex composition. Iron(III), arsenic(V), antimony(V), gold(III), thallium(III)J bismuth(III), tin(IV) and selenium(IV) are extracted with diisopropyl ether from 8 M hydrochloric acid. Under these conditions tellurium(IV) is quantitatively retained in the aqueous phase. Subsequently tellurium(IV) is extracted from 4 M hydrochloric acid with methylisobutyl ketone, so that copper(II), aluminium(III), silver(I), nickel(II), cobalt(II), zink(II), cadmium(II) and lead(II) remain in. the aqueous phase. The complete separation of the accompanying elements is realized by an additional extraction of their cupferronates with methylisobutyl ketone at pH 3–5. The separation described can be combined with any known method for the determination of small amounts of tellurium(IV).

     

Spectrophotometric determination of selenium with cyclohexanone

Selenium (2-100 mug) can be determined directly in the aqueous phase by formation of the ketone-chloro complex with cyclohexanone in ~7M hydrochloric acid from either selenium(IV) or selenium(VI), the reaction being brought to completion by heating for 5 min in a boiling water-bath.     

Extraction chromatography with bis(2-ethylhexyl)phosphoric acid for separation of tin(IV)

Tin is extracted from 0.01M hydrochloric acid on a silica-gel column impregnated with bis(2-ethylhexyl)phosphoric acid, stripped with 5M hydrochloric acid, and then determined spectrophotometrically as its Pyrocatechol Violet complex at 555 nm. Tin has been separated from several multicomponent mixtures containing arsenic, antimony, bismuth, lead and copper, and determined in various alloys.     

Catalytic determination of ultratrace amounts of selenium(iv)

A new sensitive catalytic method for determining selenium(IV) is proposed. Selenium catalyzes the oxidation of p-hydrazinobenzenesulfonic acid to p-diazobenzenediazonium ion, which then is converted to a yellow azo dye by coupling with m-phenylenediamine. As little as 10^-7 M selenium(IV) can be determined easily; the effective molar absorptivity is 1.2 · 10⁶ for selenium(IV). If the azo dye is extracted into an organic solvent, the effective molar absorptivity can be increased further to 2.4· 10⁶ for selenium(IV).