Structural characterization of mullites synthesized by thermal decomposition of topaz

Soares, Robson de Miranda; Sabioni, Antônio Claret Soares; Resck, Inês Sabioni; Falcomer, Viviane Aparecida Silva; Dias, José Alves; Silva, Naira Machado da; Menezes, Sônia Maria Cabral de; Costa, Geraldo Magela da

doi:10.1590/S1516-14392007000100016

Abstract

The structure of mullite obtained by thermal decomposition of topaz at 1340 °C and after additional thermal treatment at 1600 °C was characterized by 29Si and 27Al MAS NMR spectroscopy and x ray diffraction. No amorphous phase was detected by these techniques. The 29Si MAS NMR spectra of the mullite samples showed four resonance peaks at -81, -86, -90 and -94 ppm. The peak at -81 ppm corresponded to silicon near oxygen vacancies in the mullite structure. The peak at 86 ppm was related to a sillimanite-type site and was the major contribution, ranging from 42 to 50%. The two other peaks, at -90.0 ppm and -94 ppm, were interpreted as resulting from rearrangements of the sillimanite-type site by the replacement of AlO4 by SiO4 tetrahedra16. The 27Al MAS NMR data of the two samples exhibited three different peaks, two of which were attributed to tetrahedral sites at 40 -45 and 63 -67 ppm, while the third was assigned to an octahedral site at about -6 ppm. The ratio of tetrahedral to octahedral aluminum sites was found to depend on the temperature applied during the preparation of the mullite and was higher at 1600 °C.

mullite synthesis; topaz; characterization; 27Al and 29Si MAS NMR, XRD

Structural characterization of mullites synthesized by thermal decomposition of topaz

Robson de Miranda Soares^I; Antônio Claret Soares SabioniI, ^* * e-mail: sabioni@iceb.ufop.br ; Inês Sabioni Resck^II; Viviane Aparecida Silva Falcomer^II; José Alves Dias^II; Naira Machado da Silva^III; Sônia Maria Cabral de Menezes^IV; Geraldo Magela da Costa^V

^ILaboratório de Difusão em Materiais, Departamento de Física, Universidade Federal de Ouro Preto, 35400-000 Ouro Preto - MG, Brazil

IILaboratório de Ressonância Magnética Nuclear, Instituto de Química, Universidade de Brasília, CP 4478, 70904-970 Brasília - DF, Brazil

^IIIPontifícia Universidade Católica do Rio de Janeiro PUC/RJ, Rua Marquês de São Vicente, 225, 22451-041 Rio de Janeiro - RJ, Brazil

^IVCENPES/PETROBRÁS, Avenida 1, Quadra 7, Cidade Universitária, Ilha do Fundão, 21949-900 Rio de Janeiro - RJ, Brazil

^VDepartamento de Química, Universidade Federal de Ouro Preto, 35400-000 Ouro Preto - MG, Brazil

ABSTRACT

The structure of mullite obtained by thermal decomposition of topaz at 1340 °C and after additional thermal treatment at 1600 °C was characterized by ²⁹Si and ²⁷Al MAS NMR spectroscopy and x ray diffraction. No amorphous phase was detected by these techniques. The ²⁹Si MAS NMR spectra of the mullite samples showed four resonance peaks at -81, -86, -90 and -94 ppm. The peak at -81 ppm corresponded to silicon near oxygen vacancies in the mullite structure. The peak at 86 ppm was related to a sillimanite-type site and was the major contribution, ranging from 42 to 50%. The two other peaks, at -90.0 ppm and -94 ppm, were interpreted as resulting from rearrangements of the sillimanite-type site by the replacement of AlO₄ by SiO₄ tetrahedra¹⁶. The ²⁷Al MAS NMR data of the two samples exhibited three different peaks, two of which were attributed to tetrahedral sites at 40 -45 and 63 -67 ppm, while the third was assigned to an octahedral site at about -6 ppm. The ratio of tetrahedral to octahedral aluminum sites was found to depend on the temperature applied during the preparation of the mullite and was higher at 1600 °C.

Keywords: mullite synthesis, topaz, characterization, ²⁷Al and ²⁹Si MAS NMR, XRD

1. Introduction

Mullite is an aluminum silicate widely used in traditional and advanced ceramic materials thanks to its low thermal expansion, low thermal conductivity, and excellent creep resistance. Mullite occurs as solid solution in the silica-alumina binary system^1,2 and can be described by the following general formula: Al_4+2xSi_2-2xO_10-x, in which x ranging from 0.17 to 0.59 denotes the number of oxygen vacancies per average unit cell¹. The end members of this general formula are sillimanite mineral (x = 0) and iota-alumina (x = 1). In general, the mullite compositions are non-stoichiometric. However, there are stoichiometric compositions such as 3Al₂O₃.2SiO₂ (3:2 mullite), for x = 0.25, or 2Al₂O₃.SiO₂ (2:1 mullite), for x = 0.4, in which the Al₂O₃/SiO₂ ratio is equal to 1.5 and 2.0, respectively. The mullite structure consists of chains of edge-sharing AlO₆ octahedra running parallel to the crystallographic c-axis and crosslinked by double chains of aluminum-oxygen and silicon-oxygen tetrahedra, which also run parallel to the c-axis³. This compositional variation in mullite occurs due to the substitution of silicon for aluminum with the simultaneous formation of oxygen vacancies, which can be described by means of a defect formation reaction using Kröger-Vink notation, as follows⁴:

Increasing the number of oxygen vacancies per unit cell (x) causes the tetrahedral double chains to become gradually disarranged by removal of bridging oxygen atoms, leading to the formation of new Al^*O₄ tetrahedra⁵. Thus, the higher the x value the higher the tetrahedral aluminum to silicon ratio. The crystal structure of mullite has been reviewed elsewhere^3-6.

Due to the technological importance and widespread industrial use of mullite, which is rare in nature as a mineral, a number of processes to produce synthetic mullites have been designed¹. One of these methods involves the preparation of mullite from topaz mineral^7,8, which is a fluorine aluminum silicate whose chemical formula is Al₂SiO₄[F_y(OH)_1-y]₂⁷. This is a very attractive option, since high-purity colorless topaz is abundant in nature and its gemological or commercial value is low⁸. Moreover, the transformation of topaz to mullite is a clean procedure which does not form chemical residues, in line with the principles Green Chemistry.

This work deals with the structural characterization of mullite synthesized from topaz mineral, using ²⁹Si and ²⁷Al magic angle spinning nuclear magnetic resonance (MAS NMR) spectroscopy and x ray diffraction (XRD) experiments. An investigation was made into the possible presence of amorphous phase, and the local silicon and aluminum environments in the structure of mullites synthesized at 1340 °C and heat-treated at 1600 °C, which are temperatures frequently used in the fabrication of mullite ceramics by sintering.

2. Experimental Procedure

The colorless, transparent and high purity topaz used in this work to produce mullite originated from the state of Minas Gerais, Brazil. The chemical composition of this topaz is shown in Table 1. The topaz was milled in a wet ball mill, using the material itself as the grinding medium (autogenous grinding). After milling, the topaz suspension was oven-dried, followed by heat treatment of the resulting topaz powder in an electric furnace to transform the topaz into mullite. The preparation of mullite by thermal decomposition of topaz occurs through the loss of fluorine, hydrogen and silicon as gases HF, H₂O and SiF₄^7-9. This transformation occurs only at temperatures exceeding 1000 °C and can be achieved completely at 1300 °C. Two different mullite samples were prepared: M400 at 1340 °C, and M500 at 1600 °C. The M400 mullite was obtained by the thermal decomposition of topaz at 1340 °C for 3 hours, as indicated in the thermal cycle shown in Figure 1. In the case of the M500 sample, the thermal decomposition was followed by heat treatment at 1600 °C for 4 hours. The mullite was chemically analyzed by x ray fluorescence (XRF) and microstructurally characterized by scanning electron microscopy (SEM) (Model JSM 5510, JEOL, Japan). Powder x ray diffraction (XRD) patterns were recorded to analyze the topaz to mullite transformation and the effect of temperature on the mullite structure. The samples were examined by XRD using a diffractometer (Model Shimadzu XRD6000) with FeKa radiation and a graphite monochromator. The scanning rate used was 2°/minutes in the 15-70° range (2q). Silicon was used as the internal standard. The diffraction data were analyzed using JADE software after subtracting background and stripping the Ka2 pattern. ²⁹Si and ²⁷Al MAS NMR experiments were performed on a spectrometer (VARIAN MERCURY plus -7.05 T) at frequencies of 59.6 and 78.2 MHz, respectively. The spectrometer was equipped with a 7 mm CP/MAS probe and the samples were packed in zirconia rotors and spun at the magic angle at 4 and 6 kHz for ²⁹Si and ²⁷Al, respectively. ²⁹Si MAS spectra were acquired using a spectral width of 100 kHz, a single pulse duration of 7.5 µs (p/2), a recycle delay of 30 seconds, and an acquisition time of 0.05 seconds, with 500 scans accumulated and referenced to tetramethylsilane (TMS). A line broadening of 10 Hz and a Gaussian function of 0.003 seconds were applied to process the spectra. The ²⁹Al MAS spectra were recorded using a spectral width of 100 kHz, acquisition time of 0.05 seconds, a single pulse duration of 1.0 µs (p/20), and a recycle delay of 0.3 seconds, with 15000 scans accumulated and externally referenced to Al(H₂0)₆³⁺ (0.0 ppm). The spectra were processed using a line broadening of 25 Hz. The ²⁹Si and ²⁷Al MAS NMR spectra were deconvoluted by the NUTS program. All the ²⁹Si and ²⁷Al spectra were fitted to a sum of partial Gaussian/Lorentzian lines using a gradient algorithm that optimizes the position, width and amplitude of each line.

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3. Results and Discussion

The x ray fluorescence analysis of the mullite indicated an Al₂O₃ content of 62.0 ± 0.5 (mol %) in the M400 and M500 samples, corresponding to a nonstoichiometric mullite composition with an Al₂O₃/SiO₂ ratio of 1.63. The number of oxygen vacancies per average unit cell (x) was calculated by means of the expression¹⁰:

where m is the alumina content in the mullite (mol %). The x-value for the M400 and M500 samples was found to be 0.30. It is worth noting that the Al/Si ratio increased from 2 in topaz to 3.26 in the M400 and M500 samples. This increase was due to the loss of silicon in the form of SiF₄ gas during the thermal decomposition of topaz. Figure 2 shows a SEM micrograph of mullite obtained by thermal decomposition of topaz at 1340 °C for 3 hours. This mullite showed a needle-like microstructure (mullite whiskers), which is characteristic of mullite obtained by the decomposition of topaz⁸.

The experimental conditions used here resulted in very pure mullite without amorphous phase, as depicted in Figures 3a and 3c. No topaz phase was visible in the XRD pattern of the prepared mullites (M400 and M500). Table 2 shows the lattice parameters and the unit cell volumes of M400 and M500 samples obtained by x ray diffraction. As can be seen in these figures, increased temperatures did not significantly modify the mullite crystalline structure. X ray diffraction data has proved to be a useful tool to estimate the alumina content in mullite. Several authors, working with mullite solid solutions obtained by different processes, have found a linear dependence between alumina content (m) and the a-lattice parameter. Using, for example, the relationship established by Fischer et al.¹⁰ as follows:

one finds an alumina content of 63.35 ± 1.50 (% mol) in mullite obtained from topaz, which is reasonably consistent with the value of 62.0 mol % found in our x ray fluorescence analysis.

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²⁹Si and ²⁷Al MAS NMR experiments were used for the first time to characterize the structure of mullite obtained from topaz, and led to the determination of the local environment of silicon and aluminum atoms in the structure of the M400 and M500 samples.

According to the literature, the structure of mullite from different sources and with various compositions has four NMR silicon tetrahedral sites typically at -81, -86, -90 and -94 ppm^11-20. These local environments of Si atoms were also observed in the structure of mullite obtained from topaz, and were similar in the M400 and M500 samples. Figure 4 shows the ²⁹Si MAS NMR deconvoluted spectra of the M400 and M500 samples. The high frequency peaks at -81.0 and -80.7 ppm, determined with 22 and 18%, respectively, for the M400 and M500 samples, are assigned to the local arrangement of the (Si, Al, Al^*) cluster¹³ and correspond to silicon near oxygen vacancies in the mullite structure¹⁷. Site 2 at -86.3 ppm in both samples is related to a sillimanite-type site^16-21 and corresponded to the major contribution, which ranged from 42 to 50%. The two other peaks at -90.0 ppm (25-29%) and -93.9 ppm (7%) were interpreted as resulting from rearrangements of the sillimanite-type site by the replacement of one or two AlO₄ by SiO₄ tetrahedra¹⁶. A possible amorphous phase in the mullite would generate a resonance peak at around -110 ppm¹¹²⁰, which was not observed at the ²⁹Si spectra shown in Figure 4, thus corroborating our x ray diffraction measurements.

Figure 5 illustrates the deconvoluted ²⁷Al MAS NMR spectra of the M400 and M500 samples, showing three distinct signals for aluminum sites. These signals were attributed to an octahedral site and two tetrahedral sites, and have also been detected in other mullites obtained from different sources^18-20,22. In the samples used in this work, an octahedral site at -5.7 ppm and two tetrahedral sites at 45.0 and 67.0 ppm were observed in the structure of the M400 sample, while the same three sites were assigned to -6.0, 40.0 and 63.0 ppm in the M500 sample. The intensity of the tetrahedral occupancy at 63.0 ppm in the M500 sample increased (16 ® 33%) after the sample was heat-treated at 1600 °C, while the octahedral one at -6.0 ppm decreased (51 ® 32%), revealing three signals with approximately the same intensities (33: 35: 32).

4. Conclusions

²⁷Al and ²⁹Si MAS NMR and x ray diffraction was used to characterize the mullite structures obtained by heat-treating topaz at 1340 °C and 1600 °C. Neither of these techniques revealed any amorphous phase in the various mullite samples. The four resonance peaks in the ²⁹Si spectra at -81, -86, -90 and -94 ppm, obtained by simulation with Gaussian/Lorentzian functions, were nearly the same at 1340º and 1600 °C, with the main contribution (42-50%) represented by the sillimanite-type site at -86 ppm. The ²⁷Al MAS NMR data revealed three different peaks in the mullite samples, two of which were attributed to tetrahedral sites at 40-45 and 63-67 ppm while the third was assigned to an octahedral site at about -6 ppm. The tetrahedral to octahedral aluminum site ratio, which was found to depend on the heat-treatment temperature, was higher at 1600 °C.

Acknowledgments

The authors are grateful to FAPEMIG, CNPq, IQ|UnB and FINEP (grant CT-INFRA 970/2001) for financial support, and also to CENPES PETROBRAS.

Received: September 18, 2006; Revised: February 1, 2007

1. Schneider H, Okada K, Pask JA. Crystal chemistry of mullite, pp. 4-30 in: Mullite and Mullite Ceramics England: John Wiley & Sons Ldt; 1994.
2. Pask JA. Importance of starting materials on reactions and phase equilibria in the Al₂O₃-SiO₂ system. Journal European Ceramic Society 1996; 16(14):101-108.
3. Johnson BR, Kriven WM, Schneider J. Crystal structure development during devitrification of quenched mullite. Journal European Ceramic Society 2001; 21(14):2541-62.
4. Fielitz P. et al. Self-diffusion of Oxygen in Mullite. Journal European Ceramic Society 2001; 21(14):2577-82.
5. Schneider H, Eberhard E. Thermal expansion of mullite. Journal American Ceramic Society 1990; 73(67):2073-76.
6. Cameron WE. Mullite-substituted alumina. American Mineralogist 1977; 62(7-8):747-55.
7. Sabioni ACS. et al. Imperial topaz from Ouro Preto, Brazil: chemical character and thermal behaviour. Journal Gemmology 2003; 28(5):283.
8. Monteiro RR, Sabioni ACS, Costa GM. Preparação de mulita a partir do mineral topázio. Cerâmica 2004; 50(316):318-23.
9. Day RA, Vance ER, Cassidy DJ. The topaz to mullite transformation on heating, J. Materials Research 1995; 10(11):2963-69.
10. Fischer RX, Schneider H, Voll D. Formation of Aluminium Rich 9:1 Mullite and its Transformation to Low Alumina Mullite upon Heating. Journal European Ceramic Society 1996; 16(2):109-113.
11. Merwin LH. et al. ²⁹Si and ²⁷Al MAS NMR Spectroscopy of Mullite. Phys. Chem. Minerals 1991; 18(7):47-52.
12. Schneider H, Merwin LH, Sebald A. Mullite formation from noncrystalline precursors. Journal Material. Science 1992; 27(3):805-12.
13. Ban T, Okada K. Analysis of local cation arrangement in mullite using ²⁹Si magic-angle spinning nuclear magnetic resonance spectra. Journal American Ceramic Society 1993; 76(10):2491-96.
14. Selvaraj U, Komarneni S, Roy R. Structure differences in mullite xerogels from different precursors characterized by ²⁷Al and ²⁹Si MAS NMR. J. Solid State Chem. 1993; 106(1):73-82.
15. Jaymes L. et al. New synthesis of mullite. Structural evolution study by ¹⁷O, ²⁷Al and ²⁹Si MAS NMR Spectroscopy. J. P. J. Sol-Gel Sci. Technol. 1994; 2(1-3):367-70.
16. Jaymes I. et al. Evolution of the Si environment in mullite solid solutions by ²⁹Si MAS-NMR spectroscopy. Journal of Non-Crystalline Solids 1996; 204(2):125-134.
17. Gomes S, François M. Characterization of mullite in silicoaluminous fly ash by XRD, TEM, and ²⁹Si MAS NMR. Cem. Concr. Res. 2000; 30:175-81.
18. Zhao H, Hiragushi K, Mizota Y. ²⁷Al and ²⁹Si MAS-NMR studies of structural changes in hybrid aluminosilicate gels. Journal European Ceramic Society 2002; 22(9-10):1483-91.
19. Zhao H, Hiragushi K, Mizota, Y. Phase segregation on non-stoichiometric aluminosilicate gels characterized by ²⁷Al and ²⁹Si MAS-NMR. Journal of Non-Crystalline Solids 2002; 311:99-206.
20. He H. et al. ²⁹Si and ²⁷Al MAS NMR spectra of mullite from different kaolinites. Spectrochim. Acta Part A 2004; 60(5):1061-1064.
21. Schmucker M. et al. AlO₄/SiO₄ distribution in tetrahedral double chains of mullite. Journal American Ceramic Society 2005; 88(10):2935-2937.
22. Bodart PR. et al. Aluminium environments in mullite and an amorphous sol-gel precursor examined by ²⁷Al triple-quantum MAS NMR. J. Phys. Chem. Solids 1999; 60(2):223-228.

*

e-mail:

sabioni@iceb.ufop.br

Publication Dates

Publication in this collection
03 May 2007
Date of issue
Mar 2007

History

Accepted
01 Feb 2007
Reviewed
01 Feb 2007
Received
18 Sept 2006

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] 1. Schneider H, Okada K, Pask JA. Crystal chemistry of mullite, pp. 4-30 in: Mullite and Mullite Ceramics England: John Wiley & Sons Ldt; 1994.

[2] 2. Pask JA. Importance of starting materials on reactions and phase equilibria in the Al₂O₃-SiO₂ system. Journal European Ceramic Society 1996; 16(14):101-108.

[3] 3. Johnson BR, Kriven WM, Schneider J. Crystal structure development during devitrification of quenched mullite. Journal European Ceramic Society 2001; 21(14):2541-62.

[4] 4. Fielitz P. et al. Self-diffusion of Oxygen in Mullite. Journal European Ceramic Society 2001; 21(14):2577-82.

[5] 5. Schneider H, Eberhard E. Thermal expansion of mullite. Journal American Ceramic Society 1990; 73(67):2073-76.

[6] 6. Cameron WE. Mullite-substituted alumina. American Mineralogist 1977; 62(7-8):747-55.

[7] 7. Sabioni ACS. et al. Imperial topaz from Ouro Preto, Brazil: chemical character and thermal behaviour. Journal Gemmology 2003; 28(5):283.

[8] 8. Monteiro RR, Sabioni ACS, Costa GM. Preparação de mulita a partir do mineral topázio. Cerâmica 2004; 50(316):318-23.

[9] 9. Day RA, Vance ER, Cassidy DJ. The topaz to mullite transformation on heating, J. Materials Research 1995; 10(11):2963-69.

[10] 10. Fischer RX, Schneider H, Voll D. Formation of Aluminium Rich 9:1 Mullite and its Transformation to Low Alumina Mullite upon Heating. Journal European Ceramic Society 1996; 16(2):109-113.

[11] 11. Merwin LH. et al. ²⁹Si and ²⁷Al MAS NMR Spectroscopy of Mullite. Phys. Chem. Minerals 1991; 18(7):47-52.

[12] 12. Schneider H, Merwin LH, Sebald A. Mullite formation from noncrystalline precursors. Journal Material. Science 1992; 27(3):805-12.

[13] 13. Ban T, Okada K. Analysis of local cation arrangement in mullite using ²⁹Si magic-angle spinning nuclear magnetic resonance spectra. Journal American Ceramic Society 1993; 76(10):2491-96.

[14] 14. Selvaraj U, Komarneni S, Roy R. Structure differences in mullite xerogels from different precursors characterized by ²⁷Al and ²⁹Si MAS NMR. J. Solid State Chem. 1993; 106(1):73-82.

[15] 15. Jaymes L. et al. New synthesis of mullite. Structural evolution study by ¹⁷O, ²⁷Al and ²⁹Si MAS NMR Spectroscopy. J. P. J. Sol-Gel Sci. Technol. 1994; 2(1-3):367-70.

[16] 16. Jaymes I. et al. Evolution of the Si environment in mullite solid solutions by ²⁹Si MAS-NMR spectroscopy. Journal of Non-Crystalline Solids 1996; 204(2):125-134.

[17] 17. Gomes S, François M. Characterization of mullite in silicoaluminous fly ash by XRD, TEM, and ²⁹Si MAS NMR. Cem. Concr. Res. 2000; 30:175-81.

[18] 18. Zhao H, Hiragushi K, Mizota Y. ²⁷Al and ²⁹Si MAS-NMR studies of structural changes in hybrid aluminosilicate gels. Journal European Ceramic Society 2002; 22(9-10):1483-91.

[19] 19. Zhao H, Hiragushi K, Mizota, Y. Phase segregation on non-stoichiometric aluminosilicate gels characterized by ²⁷Al and ²⁹Si MAS-NMR. Journal of Non-Crystalline Solids 2002; 311:99-206.

[20] 20. He H. et al. ²⁹Si and ²⁷Al MAS NMR spectra of mullite from different kaolinites. Spectrochim. Acta Part A 2004; 60(5):1061-1064.

[21] 21. Schmucker M. et al. AlO₄/SiO₄ distribution in tetrahedral double chains of mullite. Journal American Ceramic Society 2005; 88(10):2935-2937.

[22] 22. Bodart PR. et al. Aluminium environments in mullite and an amorphous sol-gel precursor examined by ²⁷Al triple-quantum MAS NMR. J. Phys. Chem. Solids 1999; 60(2):223-228.

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Structural characterization of mullites synthesized by thermal decomposition of topaz

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