RU2024850C1 - Method for photometric determination of titanium - Google Patents

Abstract

FIELD: photometric determination of titanium. SUBSTANCE: method consists in conversion of titanium into ionic associate with brompyrogallol red and crystalline violet and its flotation at pH 0.75-0.83 with toluene and subsequent disintegration with ethanol and separation of crystalline violet into amount equivalent to titanium amount. Quantitative registration is effected by photometric evaluation of toluene-ethanol extract at 590 nm. Associate formation conditions: concentration of brompyrogallol red (1.6-2.4) (1,6-2,4)·10^-4 M and concentration of crystalline violet (1.2-1.6) (1,2-1,6)·10^-4 M. EFFECT: higher efficiency. 1 tbl

Description

 The invention relates to the field of chemistry, and more particularly to photometric methods for determining titanium in various objects.

Photometric methods for determining titanium are known, based on the reaction of its interaction with bromopyrogallol red and organic bases - cationic surface-active substances (surfactants) cetyltrimethylammonium and cetylpyridinium (CP). The maximum value of the molar absorption coefficient is 2.6˙10 ⁴ . These methods do not have high sensitivity and selectivity with respect to titanium.

Closest to the invention is a method for photometric determination of titanium, including its interaction with bromopyrogallol red (BOD) and two surfactants - cationic CP and non-ionic OP-10 with the formation of the ion associate Ti-BPK-CP-OP-10 (3). This method consists in the following: in an environment close to neutral pH 6.5-7.5 when the solution contains 1˙10 ^-4 M BOD, 1.4˙10 ^-4 M CPU and 8˙10 ^-4 M OP-10 titanium forms an ionic associate of Ti-BOD-CP-OP-10 with a ratio of components Ti: BOD: CPU = 1: 4: 4. The molar coefficient of light absorption is 6.3˙10 ⁴ , λ _max = 620 nm. The calibration graph is linear at a titanium concentration of 2.0-20 μg in 25 ml of solution. The minimum detectable concentration of titanium, calculated by the formula C _min = 0.05 / ε ˙ l (0.05 is the reliably measurable optical density; l is the cell layer thickness = 1 cm, ε is the molar absorption coefficient) is 7.9˙ 10 ^-7 M.

 The determination of titanium does not interfere with 10-fold excesses of Cu, Ni, Pb and Mn.

 This method has a low sensitivity and selectivity.

 The purpose of the invention is to increase the sensitivity and selectivity of the determination of titanium.

This goal is achieved by the fact that in the method for the photometric determination of titanium, including processing the sample with bromopyrogallol red and an organic base followed by photometry, the sample is treated with bromopyrogallol red and the main dye crystalline violet at concentrations of (1.6-2.4) ˙10 ^-4 M and (1.2-1.6) ˙10 ^-4 M, respectively, and a pH of 1.5-2.5; the resulting ionic associate is floated with toluene from a pH of 0.75-0.85 medium, it is separated from the aqueous phase, washed with water, the flotated precipitate is dissolved in ethanol and the resulting solution is photometric.

 The essence of the invention is to replace the colorless organic bases of the surface-active substances CP and OP-10 of the prototype with an intensely colored main dye KF in the proposed method. The ratio of Ti: BOD: CF = 1: 2: 2.

The use of CF and the flotation of the associate, followed by washing with water and destruction in the ash, with the release of the amount of CF equivalent to titanium, led to an increase in the molar absorption coefficient of the associate to 2˙10 ⁵ instead of 6.7˙10 ^-4 in the prototype. The minimum detectable concentration of titanium is 2.5 × 10 ^-7 M.

 The decrease in the acidity of the solution from pH 6.5-7.5 to pH 0.75-0.85 during the flotation of the associate increased the selectivity of the reaction. The determination of titanium does not interfere with Cu, Ni, Pb, Mn and other divalent metals.

Other main dyes of triphenylmethane series (methyl violet, brilliant green and malachite green). They are also able to form corresponding associates with titanium and BOD. However, the molar absorption coefficients of these associates are significantly lower and amount to (0.9-1.3) ˙10 ⁵ depending on the dye used. Such a decrease in ε associates is due to a less intense coloration of the dyes themselves and a decrease in the degree of flotation of associates with toluene. In addition, flotation of associates with other dyes occurs in a less acidic environment.

Only oxygen-free solvents can be used as a flotation agent: benzene, xylene, toluene. The latter is selected as the least toxic, which at the same time has a high degree of flotation. Oxygen-containing solvents such as alcohols, ketones, etc. cannot be used because of the high floatability of the BPK-KF associates, and therefore, the high OD value of the blank solution (A _chol ≈ 2.0), against which it is impossible to determine the trace amounts of titanium.

When the titanium concentration goes beyond the limits of Beer's law, the optical density is underestimated. At a concentration lower than the lower limit (0.13 μg in 10 ml or 2.7˙10 ^-6 M), due to large excesses of BOD and CF in relation to titanium, a blank sample of the solution begins to influence, the light absorption spectrum of which is superimposed on the spectral curve of the solution ionic associate. In addition, at low titanium concentrations, and consequently, low optical density values ≈ 0.03, the error associated with the device itself, the spectrophotometer, the so-called instrument error of analysis increases. At a titanium concentration above the upper limit (1.6 μg in 10 ml or 3.35˙10 ^-5 M), the optical density also does not reach its optimum value due to the lack of dyes for binding the titanium complex with BOD to associate with crystalline violet. A decrease in optical density is also observed when going beyond the optimal values of BOD and CF. If BOD is taken less than 1.6˙10 ^-4 M, then it becomes insufficient to complete the formation of the ionic associate, which entails a decrease in optical density. With excess quantities> 2.4˙10 ^-4 M BOD, the optical density is underestimated due to the higher optical density of the blank solution. The same thing happens when you go beyond the boundary concentrations of crystalline violet. At a concentration of CF <1.2˙10 ^-4 M, the completeness of formation of the ionic associate is not achieved, which reduces its optical density. With an increase in the concentration of CF> 1.6˙10 ^-4 M, the optical density of the blank experiment increases, due to which the optical density of the associate solution decreases.

 With a decrease in pH <0.75, the optical density of the ionic associate solution decreases due to a decrease in its floatability. With an increase in acidity, pH> 0.85, the BOD-KF compound begins to float and the blank sample becomes highly colored.

 The developed method was used to determine titanium in thin magnetic films of the Fe-Ni-Co-Ti system made on glass substrates. A feature of the analysis of such films because of the small thickness of a few microns and a mass of 0.2-2 mg is their dissolution without taking a sample and the determination of the weight content of each of the components in the solution, followed by the calculation of their% content, based on the total mass in μg.

 For the determination of iron, the reaction of formation of a complex compound with 1,10-phenanthroline was used, dimethylglyoxime was taken for the determination of nickel, and the nitroso-R salt was used for cobalt. These reactions are not highly sensitive, although selective, so that most of the solution is spent on their determination.

 Due to the low titanium content in the film, of the order of 2%, the entire solution contains from 4 to 40 μg of titanium, i.e. 0.16-1.6 μg in ml with a flask volume of 15 ml. Therefore, the determination of titanium requires a highly sensitive reaction, which is achieved by the invention.

Film dissolution. The film washed in distilled water is placed in a glass jar. 50 ml and dissolved by heating in HCl (1: 1). The solution was transferred to a volumetric flask. 25 ml and add to the mark with water. The course of analysis. To determine titanium, an aliquot of the solution, subject to Beer's law, is placed in a 100 ml separatory funnel, 1 ml of 1% ascorbic acid solution, 2 ml of buffer solution with pH 2, 1 ml of 2˙10 ^-4 M BOD are added, 0 , 7 ml of 2-10 ^-4 M KF, 0.3 ml of 2M HCl solution to create a pH of 0.8 and adjusted with water to 5 ml. The solution is floated with 5 ml of toluene for 1 min, the aqueous portion is separated and the organic phase is washed with 5 ml of water. After separation of the aqueous phase, 5 ml of ethanol is added to the toluene solution, the flotated precipitate is dissolved by shaking, and the optical density of the toluene-ethanol solution is measured at 590 nm in a cuvette with l = 1 cm relative to the blank test solution. In this case, the maximum value of the optical density is reached, and therefore, ε, which is equal to 2˙10 ⁵ . The method for determining titanium under other conditions is carried out similarly. Examples of the determination of titanium are given in table. The error in the determination of titanium is 2-5%. The titanium content is calculated according to the calibration graph, built on a standard solution of titanium 1˙10 ^-4 M. Iron (II), nickel and cobalt do not interfere with the determination of titanium. Due to the fact that after dissolution of the film, iron passes into iron (III), it is reduced to iron (II) using ascorbic acid.

Claims (1)

METHOD FOR PHOTOMETRIC DETERMINATION OF TITANIUM, including treating a sample with bromopyrogall red and an organic base followed by photometry, characterized in that the sample is treated with bromopyrogall red and a basic crystal violet dye at concentrations of (1.6 - 2.4) · 10 ^-4 M and (1, 2 - 1.6) · 10 ^-4 M, respectively, and pH 1.5 - 2.5, the resulting ionic associate is floated with toluene from a medium with a pH of 0.75 - 0.85, it is separated from the aqueous phase, washed with water, and the floated is dissolved a precipitate in ethanol and the resulting solution is photometric.

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