Photo-Oxidation of phenosafranine and neutral red in the presence of iron(III): Determination of trace amounts of iron and phosphate

Summary Phenosafranine (Ph) and Neutral Red (NR) in the presence of iron(III) are decolorized by illumination with light of wavelength shorter than 360 nm. The decolorization mechanism involves ·OH radicals, formed during the photo-excitation of hydrolysed iron(III) species. In the presence of oxygen, iron(III) acts as a catalyst in the photochemical process. The photo-oxidation of Ph and NR is followed by measuring the decrease in absorbance of the dyes, and linear calibration graphs in the range 1–11 ppm of iron are obtained. The decrease in the fluorescence of phenosafranine has also been used to measure the photo-oxidation of this dye, and is linearly related to iron concentration in the range 0.1–1.1 ppm. Phosphate strongly inhibits the iron(III)-catalysed photodecolorization and this can be made the basis of a method for its determination (concentration limit 1×10^–5 M).

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Photooxydation von Phenosafranin und Neutralrot in Gegenwart von Eisen(III): Bestimmung von Spuren Eisen und Phosphat

Zusammenfassung Phenosafranin (Ph) und Neutralrot (NR) werden in Gegenwart von Fe(III) durch Belichtung unter 360 nm entfärbt. Der Mechanismus dieses Vorgangs erfordert die Gegenwart von OH-Radikalen, die sich bei Belichtung von hydrolysierten Fe(III)-Verbindungen bilden. In Gegenwart von Sauerstoff wirkt Fe(III) als Katalysator der photochemischen Reaktion. Die Photooxydation von Ph und NR läßt sich durch Abnahme der Absorbanz der beiden Farbstoffe verfolgen. Dabei ergeben sich lineare Eichkurven für 1–11 ppm Fe. Die Abnahme der Fluoreszenz von Ph dient ebenfalls zur Messung der Photooxydation dieses Farbstoffes und verläuft für 0,1–1,1 ppm Fe linear. Phosphat hindert die Fe(III)-katalysierte Photoentfärbung, was als Grundlage für die Phosphatbestimmung bis zu 1×10^–5 M dienen kann.

     

Microdetermination of fluoride in the presence of phosphate by potentiometric titration

Summary A method for the microdetermination of fluoride in the presence of phosphate is described. Up to a 10-fold excess of phosphorus (as phosphate) can be tolerated. Phosphate is adsorbed on zinc oxide which is added in excess and need not be removed prior to titration of fluoride. Fluoride is determined potentiometrically with 0.02M lanthanum(III) at p_H 5 to 7. A fluoride ion specific electrode is used with an expanded-scale p_H meter to monitor the emf.

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Zusammenfassung Eine Mikrobestimmung von Fluorid in Gegenwart von Phosphat wurde beschrieben. Phosphat stört bis zu einer zehnfachen Phosphormenge nicht. Es wird an Zinkoxid adsorbiert, das man im Überschuß zusetzt und das vor der Fluoridtitration nicht entfernt werden muß. Fluorid wird potentiometrisch mit 0,02-m Lanthan(III) bei p_H 5 bis 7 bestimmt. Eine für Fluorid spezifische Elektrode mit einem p_H-Meter mit gedehnter Skala wird zur Messung verwendet.

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Work performed under the auspices of the U. S. Atomic Energy Commission.     

Determination of alpha activity ratios by alpha spectrometry in the presence of large amounts of uranium

A direct evaporation method is described for the preparation of sources using stainless steel as the backing material and tetraethylene glycol (TEG) as a spreading agent in the presence of large amounts of uranium. It is shown that FWHM and tail contribution at the low energy peak due to energy degradation of the high energy peak can be optimized by heating the source under controlled conditions in a furnace at 500–600°C for about 15 min. An accuracy of 0.5–1% is demonstrated for the determination of²³⁸Pu/(²³⁹Pu+²⁴⁰Pu) alpha activity ratio in the U/Pu range of 10 to 1500 generally encountered in dissolver solution of irradiated fuel.     

Determination of the water content in muscovites containing large amounts of fluorine by karl fischer titration after fusion with silicon dioxide

Complete release of water (or of hydrogen in the lattice which is finally released as water) from muscovite containing a large amount of fluorine, requires heating above 1500°C or addition of an appropriate flux. Experimental data from differential thermal analysis, x-ray diffraction patterns and dehydration curves showed that silicon dioxide is a useful flux. Samples are mixed with a 3 : 1 (weight) ratio of silicon dioxide in a platinum crucible and heated inductively in a nitrogen stream at 1200°C. The water released is absorbed in anhydrous (1 + 1) methanol—1, 2-ethanediol and titrated by the Karl Fischer method. For a representative muscovite sample, the water contents were 4.26 ± 0.03% at 1300—1400°C and 4.35 ± 0.08% above 1500°C in the absence of silicon dioxide. When silicon dioxide was added as described, the mean result was 4.33 ± 0.01% at 1200°C (95% confidence level) with a standard deviation of 0.015 and a coefficient of variation of 0.35%.     

Spectrophotometric determination of iron(II) with 1,10-phenanthroline in the presence of large amounts of iron(III)

A study was made to establish proper conditions for the selective determination of Fe(II) by the 1,10-phenanthroline method in the presence of large amounts of Fe(III). It was shown that fe(III) is effectively masked by fluoride. The pH of the solution to be masked should be below 2.5 in order to prevent acceleration by the fluoride of aerial oxidation of Fe(II).     

Spectrophotometric determination of cobalt(II) in the presence of large amounts of iron with salicylaldehyde thiosemicarbazone

Cobalt(II) reacts instantaneously with the reagent at pH 5.0. The yellow complex has a molar absorptivity of 1.1 × 10⁴ 1 mol^?1 cm^?1. The method is applied to the determination of cobalt in steels after removal of iron with phosphate.     

Rapid determination of magnesium in the presence of calcium and phosphate by titration with cdta

A method is presented for the accurate determination of magnesium in phosphate rock and phosphoric acid down to 0.03% magnesium oxide in the presence of 0–70% phosphorus pentoxide by titration with cyclohexanediaminetetraacetic acid (CDTA). Interference from heavy metals for which inaccurate empirical corrections have previously been made in the combined magnesium and calcium titration are linearly and unequivocally determined and subtracted from the combined titration. Magnesium oxide is determined in less than 20 min after sample digestion for Ca: Mg ratios from 1:9 to 850:1.     

Determination of submilligram amounts of cobalt by ferricyanide titration with photometric end-point detection

The titrimetric determination of cobalt^II by oxidation with hexacyanoferrate(III) in ammoniacal solution, ordinarily carried out potentiometrically, can be extended to smaller amounts of cobalt by means of photometric end-point indication.     

Complexometric titration of calcium in the presence of larger amounts of magnesium

A simple and accurate titrimetric determination of calcium in the presence of larger amounts of magnesium is proposed. Calcium is extracted into a small volume of organic solvent as its glyoxal-bis(2-hydroxyanil) complex, and the calcium is titrated with EGTA. The end-point is sharp, and occurs when the red colour of the organic layer vanishes. This method has been successfully applied to the determination of calcium in sea-water with an error less than 0.1%.     

Determination of trace amounts of phosphate by flow-injection photometry

This paper describes a simple and rapid procedure for determination of traces of phosphate by means of molybdenum blue chemistry. The use of a cost-effective home-made flow cell with a long path length in combination with a light emitting diode (LED) and a photodiode (PD) is demonstrated as a simple absorbance detector for flow-injection analysis. In this method, a sample is injected into the carrier stream through an injection valve and mixed online with mixed reagent (a mixture of molybdate, bismuth, and ascorbic acid in sulfuric acid). The color intensity of the resulting association complex, molybdenum blue, is measured photometrically (_max 875 nm). The proposed method can be used to detect phosphate in the range 0.02–4.0 mg L^–1 and the precision of the proposed procedure is less than 5% at 0.1 mg L^–1 phosphorus as phosphate. The method has been successfully applied to a variety of natural water samples.     

Determination of total iron in standard rocks by spectrophotometric titration with EDTA

A method for the determination of total iron in silicate rocks is described. It is based on spectrophotometric titration of iron(III) with EDTA after decomposition in a PTFE bomb. No prior separation of interfering elements is needed. The method was tested by analysis of the U.S. Geological Survey reference rocks G-2, AGV-1, GSP-1, BCR-1 and PCC-1. The same sample solutions were also analysed by atomic-absorption spectrophotometry. The agreement with published and recommended values was good.     

Determination of uranium in the presence of iron and plutonium by Ti(III) reduction and biamperometric titration

A method is described for the determination of uranium in the presence of iron and plutonium. Ti(III) is used as the reductant in a mixture of H₂SO₄ and HNO₃. Fe(II) and Pu(III) are selectively oxidized by the nitrous acid generated in the reaction between Ti(III) and HNO₃. The U(IV) is determined by titration with K₂Cr₂O₇ using biamperometry to detect the end point. The method is applicable to a variety of nuclear materials encountered at different stages of the nuclear fuel cycle and has no bias. The precision of the method is evaluated at different levels from 100 microgram to 100 milligram. The method is simple, rapid and convenient.     

Determination of metal complexes of ethylenediaminetetraacetate in the presence of organic matter by high-performance liquid chromatography

A high-performance liquid chromatography method is described here for the determination of the Cd(II), Co(II), Cu(II), Pb(II), and Zn(II) complexes of ethylenediaminetetraacetate (EDTA) in municipal wastewaters and surface waters. The method involves separation by ion-exchange chromatography on a reversed-phase C18 column coated with ion-pair reagent, followed by post-column conversion to FeEDTA and subsequent detection by UV absorbance. Although Co(II) and Cu(II) coelute, they can be quantified by analyzing absorbance by CuEDTA2- prior to post-column conversion. The method detection limit of 6-8 x 10(-8) M (5-7 ng) is an order of magnitude improvement over previous UV absorbance post-column reaction methods. The technique can be used in the presence of organic matter encountered in matrices such as untreated wastewater without pre-concentration or sample cleanup.     

The determination of small amounts of vanadium in the presence of large amounts of uranium

To eliminate the color interference of large amounts of uranium in the determination of vanadium by the Hamner method, the vanadium was separated prior to titration by the extraction of vanadium cupferrate with chloroform. The chloroform extract was evaporated with sulfuric acid and the excess cupferron removed by oxidation with nitric acid and perchloric acid. The vanadium was reduced with ferrous ammonium, sulfate solution, the excess ferrous ion oxidized with ammonium persulfate, and the vanadium (IV) titrated with 0.02 N potassium permanganate. As little as 1.02 mg of vanadium in the presence of 5 g of uranium oxide was determined accurately by this method.     

Amperometric titration of calcium,strontium and barium and their mixtures in presence of large amounts of alkali metal salts

Trace amounts of alkaline earth metals are titrated with triethylenetetraaminehexaacetic acid; lead(II) is added as indicator and the current is measured by square-wave polarography. At pH 13.3, calcium, strontium and barium give a common end-point corresponding to the total content of alkaline earth ions. Copper and cadmium interfere but small concentrations of Ni, Al, Mg, Zn, Mn(II) and Fe(III) are tolerated. The alkaline earth metals can be determined in the presence of 1000-fold amounts of lithium and 10⁵- fold amounts of sodium or potassium ions.     

Determination of trace amounts of phosphate in river water by flow-injection analysis

A flow-injection analysis system for the determination of trace amounts of phosphate in river water has been developed. The phosphate is reacted with molybdate and Malachite Green in acidic medium to form a green species, the absorbance of which is measured at 650 nm. Phosphorus (as inorganic phosphate) can be determined at the level of several ng ml in water. Analyses can be done at a rate of up to 40 per hour.     

Potentiometric determination of lead with DTPA in the presence of large amounts of aluminium

Lead can be titrated accurately in the presence of aluminium with diethylenetriaminepenta-acetic acid, with a silver electrode system for detection of the end-point. The method is very suitable for analysis of lead glasses.     

Determination of trace amounts of iron by catalytic-adsorptive stripping voltammetry

A highly sensitive and selective voltammetric procedure is described for the determination of trace amounts of iron. The procedure is based on the adsorptive collection of an iron-thiocyanate-nitric oxide complex on a hanging mercury drop electrode. The adsorbed complex catalyzes the reduction of nitrite in solution, which gives a detection limit of 40 ppt iron (30 s accumulation). The stripping current increases linearly with iron concentration up to 80 ppb. The relative standard deviations are 4.2% and 1.6% at 0.5 ppb and 40 ppb respectively. Most of the common ions, except cobalt, do not interfere with the determination of iron. The procedure is applied to determine iron in biological samples, natural waters and analytical-grade chemicals.