Abstracts

Short Report

Potentiometric and conductometric studies on the formation of thorium molybdates as a function of pH

Shiva Prasad* and Sílvia B. Gonçalves

Departamento de Engenharia Química, CCT, Universidade Federal da Paraíba, CP 10108, 58109-970, Campina Grande - PB, Brazil.

Introduction

The chemistry of molybdenum is very prominent in both biological and industrial systems^1,2. Recent studies have shown that certain molybdates have antiviral, including anti-AIDS and antitumor activity³. Although a large number of studies have been done in the field of molybdate chemistry, the chemical state of isopolymolybdates, obtained on acidification of a molybdate solution, is not well understood because of the complexity in polymerization. Numerous species such as HMoO₄^-, H₂MoO₄, Mo₂O₇^7-, Mo₃O₁₁^4-, HMo₃O₁₁^3-, Mo₆O₁₉^2-, HMo₆O₂₁^5-, H₂Mo₆O₂₁^4- , H₃Mo₆O₂₁^3- , Mo₇O₂₄^6-, HMo₇O₂₄^5-, H₂Mo₇O₂₄^4- , H₃Mo₇O₂₄^3- , Mo₈O₂₆^4-, HMo₈O₂₆^3-, Mo₁₂O₃₇^2-, H₇Mo₁₂O₄₁^3- , H₇Mo₂₄O₇₈^5- , H₉Mo₂₄O₇₈^3- , Mo₃₆O₁₁₂^8-, etc. have been proposed^4-11_.

In earlier publication¹² one of us reported the effect of pH change on a solution of sodium molybdate and composition of mercuric molybdates. In view of the interesting results obtained, it was considered worthwhile to investigate the composition of thorium molybdates obtained by the action of Th⁴⁺ on various molybdate species at different pH levels by means of electrometric techniques, which have provided more conclusive evidence on condensation processes of vanadate, antimonate, thiotungstate and tungstate anions¹³. There is, however, no reference available in the literature on the formation of thorium molybdates as a function of pH.

Experimental

Th(NO₃)₄, Na₂MoO₄.2H₂O, oxine and different acids of extra-pure grade were used and their solutions were prepared in deionized distilled water. Concentration of sodium molybdate solutions was further verified by determining molybdenum with oxine as MoO₂(C₉H₆ON)₂ ^14ª.

The pH measurements were carried out on a Metrohm Herisau (Switzerland) pH-meter using Scott Gerate glass combination electrode. Conductivity values were recorded by employing a Metrohm conductometer. 25 mL of the titre solution was placed in the cell each time and thermostated at 25.0±0.1^oC. Using different concentrations of the reactants, a series of pH and conductometric titrations was performed both by direct and reverse methods, i.e. when thorium nitrate solution from the microburette was added to the alkali molybdate solution and vice-versa. The observed pH changes were plotted as a function of volume of the titrant added. The inflections obtained by the curves were confirmed by the pronounced maxima in dpH/dV graphs. The breaks in the conductometric titrations are located by plotting corrected conductance as a function of volume of titrant added. The same concentrations of reactants were employed in the two techniques for the sake of comparison of results. The pH and conductometric titration curves are plotted together in the same figure for similar reasons and also for the sake of brevity. The electrometric titration results are summarized in Table 1.

The precipitates obtained at the end-points were also analyzed to substantiate the electrometric results. The different thorium molybdates were prepared by mixing stoichiometric amounts of thorium nitrate solution with the respective sodium molybdate solutions. The precipitates obtained were washed several times with 20% ethanolic solution and dried in a vacuum desiccator for 40 h. An amount exactly known (ca. 2.0 g) of each of the above precipitates was dissolved in minimum quantity of hydrochloric acid and then analyzed quantitatively for molybdenum by oxine^14a and thorium as oxalate^14b. The results of analysis are given in Table 2.

Results and Discussion

When hydrochloric acid is gradually added to Na₂MoO₄, it changes to para-molybdate Mo₇O₂₄^6- and octa-molybdate Mo₈O₂₆^4- polyanions around pH 5.5 and 4.1, respectively¹². The formation of the polyanions may be represented as follows:

Normal-molybdate titrations

Using different concentrations of Na₂MoO₄ (pH 7.8) and thorium nitrate (pH 2.9) solutions, a series of pH titrations was carried out. In direct titrations (Figure 1, curve 1), when Na₂MoO₄ solution was used as titre, a gradual decrease in pH value was observed till at the stoichiometric end-point (the stage at which the reaction ends if simple double decomposition takes place), a sharp downward jump in pH was observed when the molar ratio of Th⁴⁺:MoO₄^2- is 1:2, corresponding to the formation of white colored precipitate of thorium normal-molybdate, ThO₂.2MoO₃, in the neighborhood of pH 5.3. In case of inverse titrations (Figure 1, curve 3) the pH at first gradually changes till in the vicinity of the stoichiometric end-point, when the last traces of thorium ions have been removed by precipitation, further addition of alkali molybdate causes a marked upward jump in pH and the inflection corresponds to the molar ratio for the formation of ThO₂.2MoO₃ according to the reaction:

Employing similar concentrations of the reactants, direct (Figure 1, curve 2) and reverse (Figure 1, curve 4) conductometric titrations between the solutions of thorium nitrate and sodium molybdate gave well-defined breaks at 1:2 molar ratio of Th⁴⁺:MoO₄^2- confirming the formation of thorium normal-molybdate.

Para-molybdate titrations

Sodium para-molybdate solution was prepared by addition of hydrochloric acid to Na₂MoO₄ in the molar ratio 8H:7Mo. Using different concentrations of Th(NO₃)₄ and Na₆Mo₇O₂₄, a series of pH and conductometric titrations was carried out. The slope and nature of these titration curves (Figure 2) are similar to those of the normal-molybdate. The curves provide well-defined inflections at molar ratio 3:2 of Th⁴⁺:Mo₇O₂₄^6- corresponding to the stoichiometry for the formation of para-molybdate of thorium 3ThO₂.14MoO₃ in the neighborhood of pH 4.4. The reaction can be represented as follows:

An interesting phenomenon was observed, in both pH and conductometric reverse titrations, i.e., when thorium nitrate solution was taken as titre in the cell. In the initial part of the titration the pH slightly decreases (curve 3) and conductance value increases (curve 4). This may be ascribed to the liberation of the strong acid by hydrolysis of thorium nitrate under experimental conditions. This phenomenon may further be clarified by the fact that the white turbid precipitate of thorium molybdates, which starts from the very beginning in the case of direct titrations, starts only at the stoichiometric end-point in these reverse titrations. After passing the end-point the white precipitate gets flocculated.

Similar studies on the reaction between thorium nitrate and sodium octa-molybdate did not exhibit any appreciable inflections. This may be ascribed to the small difference in pH value of the reactants; and the presence of sodium nitrate in appreciable amounts preventing the occurrence of breaks in the conductometric titration curves.

It was noted that after each addition of the titrant, it takes a little time for the pH and conductance values to become steady. A thorough stirring in the neighborhood of the equivalence point has a favorable effect. The presence of ethanol (20%) improves the position of the end-point and increases the magnitude of the jump in pH curves, as it decreases the solubility of the precipitates formed and minimizes hydrolysis and adsorption.

Analytical results

The results of the quantitative elemental analyses of the precipitates were used to calculate the proportions of the elements present in the compounds. From these proportions, the compositions of the compounds were established which were found to be the same as obtained by the electrometric techniques (see Table 2).

The present electrometric and analytical investigations confirm the formation and precipitation of two thorium molybdates, viz. normal-ThO₂.2MoO₃ and para-3ThO₂.14MoO₃ in the vicinity of pH 5.3 and 4.4, respectively.

As structure of these compounds is not known they are represented as double oxides, the manner which is usually adopted for such compounds^15,16.

Acknowledgement

The authors are indebted to the CNPq for financial assistance.

References

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13. (a) Prasad, S. An. Acad. Bras. Ci. 1981, 53, 471. (b) Prasad, S. Bull. Electrochem. 1990, 6, 163. (c) Prasad, S. Can. J. Chem. 1981, 59, 563. (d) Prasad, S. Quím. Nova. 1994, 17, 31.

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15. Standen, A.; Ex. Ed., Kirk-Othmer Encyclopedia of Chemical Technology, 2nd. Edition; Interscience Publishers; New York, 1967, v. 13, p. 782.

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Received: July 02, 1999

Presented at the XI Simpósio Brasileiro de Eletroquímica e Eletroana-lítica, Maragogi - AL, Brazil, April 5-9, 1999. Guest editor: Luis Alberto Avaca.

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