Abstract

Obtention of Nanostructured Silica Glass by Sol-Gel Process with Incorporation of Lead Compounds

Ana Maria M. Santos^a, Wander L. Vasconcelos^b

^aCentro de Desenvolvimento da Tecnologia Nuclear - CDTN/CNEN

Rua Mário Werneck s/n, 31120-970 Pampulha Belo Horizonte - MG, Brazil

^bDepartamento de Engenharia Metalúrgica e de Materiais, UFMG

Rua Espírito Santo, 35 - 2andar - Centro, 30160-030 Belo Horizonte - MG, Brazil

Received: August 15, 1998; Revised: March 30, 1999

The methodology of obtention of nanostructured glass, incorporated with lead compounds, obtained by sol-gel processing and the structural characterizations are presented. Specific surface area, porosity, pore morphology and pore size distributions of the gels were characterized with nitrogen sorption (BET) and mercury pycnometry. The pore size distributions of gels obtained using lead nitrate were more narrow than the ones observed for gels made with lead acetate. It was also observed the presence of a bimodal pore size distribution for gels produced using lead nitrate.

Keywords: sol-gel process, nanostructured silica glass, incorporation

1. Introduction

The complexity of the sol-gel process provides an enormous potential for producing new types of materials with specific properties, which are difficult or impossible to obtain using the traditional ways. Besides obtaining high homogeneity and purity of final products, the sol-gel method allows the structure to be controlled in a molecular scale, being totally open to incorporate other phases and the composition, density and pore morphology can be changed at various stages^1,2.

In the scope of development of a matrix for incorporation of waste aggressive to the environment, the sol-gel process appears as an alternative. This is due to the possibility of permitting the structural control of the matrix during intermediate stages, which is carried out through the control of process variables such as water to alkoxide molar ratio, concentration and type of catalyst, reaction sequence, etc³.

The aim of this work is to study the incorporation of lead compounds into a silica matrix employing sol-gel process. The gels were synthesized through hydrolysis and condensation of tetramethylorthosilicate (TMOS) under atmospheric pressure. The nitrogen sorption and mercury pycnometry techniques were employed to characterize the structure of silica gels. Specific surface area, porosity and pore size distributions of the gels were obtained. The porous morphology is inferred by nitrogen sorption-desorption isotherms.

2. Experimental

The gels were synthesized by sol-gel process with hydrolysis and condensation of tetramethylorthosilicate catalyzed by dilute aqueous solution with nitric acid. Lead nitrate (Pb(NO₃)₂) and lead acetate (Pb(CH₃COO)₂.3H₂O) were used as incorporation components. The sequence of the sol-gel process used in this work were: mixing the aqueous solution with TMOS, casting, gelation, aging, drying and heat treatment.

The molar ratio water to TMOS was 16, the final pH ranged between 1.5 and 4.0 and the lead weight content (in the casting solution) varied between 0.2% to 5.3%. The sols were cast and gelled inside plastic containers at room temperature. Subsequently, the gels were aged at 60 °C during 48 h and dried at 105 °C for 48 h. After drying, the gels were heat treated at 900 °C and 1000 °C. In this work, gelation time was defined as the period between casting and the moment in which the material stopped flowing inside the container when it was tilted.

3. Results and Discussion

The gelation times for gels obtained using lead nitrate presented a time period measured in days, while for gels made with lead acetate the gelation times could be expressed in hours. For gels obtained using lead nitrate, under acidic conditions (pH = 1.5), the hydrolysis rate exceeds the condensation rate, resulting in weakly branched structure and relatively long gelation times. For gels obtained using lead acetate, under less acidic conditions (pH = 4), the condensation rate increased and the hydrolysis rate decreased, resulting in shorter gelation times.

A typical dried gel cylinder was 13 mm height and 12.6 mm in diameter and it was not fragmented. Some gels heat treated at 900 °C and 1000 °C were broken.

Figures 1 and 2 present respectively the results of bulk density and specific surface area as a function of lead content for two pH ranges (variation about 0.5), while Figs. 3, 4, 5 and 6 show sorption-desorption isotherms and Figs. 7, 8 and 9 show the results of pore size distribution analyses. The lead content showed in these figures refer to lead content in the casting solution.

The bulk densities of the gels were measured using Arquimedes' method and mercury as media. At least three measurements were made per sample. The results are shown in Fig. 1. The bulk density increases with lead content, independently of the salt type used.

The specific surface area was measured by nitrogen sorption using the single point method as described in⁴. Figure 2 presents the results of specific surface area as a function of the lead content. As one can seen in Fig. 2, the specific surface area decreases as the lead content increases and, for the same pH value, it was observed no significant difference in the results between the type of lead salt used. There is a sharp drop in surface area with lead content in the case of gels obtained using lead acetate at pH 4. It can also be seen in Fig. 2 the influence of pH in the specific surface area, which was also observed in references^5,6. The pH influence can also be observed through the density results shown in Fig. 1. The decrease on surface area with the addition of dopants was also observed by Ganguli⁷.

The evaluation of the pore size distribution and the pore morphology were carried out from nitrogen sorption isotherms. The pore size distribution was determined by applying the Kelvin equation to the desorption branch of the isotherms. The pore morphology could be inferred using the de Boer work⁴. de Boer idealized five types of the hysteresis for relative pressure above 0.3 and associated the shape of the pores with the form of hysteresis curves (Fig. 10). Table 1 shows the association between hysteresis form and the geometrical shape of the pore. A more detailed description is given in reference⁴.

From Fig. 3 to Fig. 6, typical results of sorption-desorption isotherms are shown for gels incorporated by lead nitrate and lead acetate. In these figures, it can be observed that the isotherm forms varies with lead content for gels obtained by lead acetate when heat treated at 900 °C. It can also be seen in these figures, that the shape of the isotherms, with different lead content, can be associated with hysteresis curves type (a) and (e) (Fig. 10), both associated with pores of cylindrical shape.

Figures 7 and 8 present typical results of pore size distributions of gels obtained from lead nitrate and lead acetate, both heat treated at 105 °C. It can be observed, in these figures, that the pore size distribution of gels obtained using lead nitrate (Fig. 8) showed a narrow pore size distribution and a bimodal curve when compared with the pore size distribution of gels obtained using lead acetate. This bimodal behavior was also observed by Ganguli⁷, for gels obtained with TEOS and dopped with Al³⁺ e Cr³⁺.

Pore size distributions in gels obtained via lead acetate, heat treated at 900 °C and at 1000 °C, with 1.2 wt% Pb (in casting solution), presented large scattering (see Fig. 9).

4. Conclusion

The lead incorporation into silica matrix using sol-gel process by direct mixture of lead nitrate and lead acetate into the casting solution was investigated. It was possible to characterize the silica gels concerning specific surface area, bulk density and pore structure. From nitrogen sorption experiments, the sorption-desorption isotherms and pore size distributions were obtained. The cylindrical form of pores was inferred through the hysteresis curves, based on de Boer work. The pore size distributions of gels obtained using lead nitrate were more narrow than the ones observed for gels made with lead acetate. It was also observed the presence of a bimodal distribution for gels produced using lead nitrate.

Acknowledgments

The authors are grateful for the financial support of CNPq.

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