Research Article StudyofPbTiO 3 -Based Glass Ceramics Containing SiO 2

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International Scholarly Research Network ISRN Ceramics Volume 212, Article ID 82393, 5 pages doi:1.542/212/82393 Research Article StudyofPbTiO 3 -Based Glass Ceramics Containing SiO 2 V. K. Deshpande and V. U. Rahangdale Department of Applied Physics, Visvesvaraya National Institute of Technology, Nagpur 41, India Correspondence should be addressed to V. K. Deshpande, vkdeshpande@phy.vnit.ac.in Received 16 August 212; Accepted 2 September 212 Academic Editors: S. Bernik, J. Sheen, and T. Yanagida Copyright 212 V. K. Deshpande and V. U. Rahangdale. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. Glass samples with composition 5PbO : 25TiO 2 : (25-X) B 2 O 3 : XSiO 2 (with X =, 1.5, 2.5, 3.5, and 5 mol%) were prepared by conventional quenching technique. These glass samples were converted to glass ceramics by the two-stage heat treatment schedule. Formation of ferroelectric lead titanate phase in the glass ceramics was confirmed from the XRD. The density, CTE, and dielectric constant of the glass and glass-ceramic samples were measured. The glass-ceramic sample containing 2.5 mol% SiO 2 exhibited the highest dielectric constant. The SEMs of glass-ceramic samples were studied. The P-E hysteresis loop studies also revealed the highest remnant polarization for this sample, which has a potential for being developed for practical applications. 1. Introduction Lead titanate was reported to be ferroelectric in year 195 on the basis of its structural analogy with BaTiO 3.The high transition temperature around 49 C[1] exhibited by PbTiO 3 was important from high temperature application point of view. Pore-free fine-grained microstructure and better properties can be achieved through controlled crystallization [2]. The glass crystallization method by thermal treatments is attractive because it can be conducted at lower temperatures and allows greater control over phase separation and crystallization [3]. The controlled crystallization of the perovskite PbTiO 3 was reported by Herczog [4]. Undoped perovskite titanate such as PbTiO 3 has been extensively studied [5]. A lot of work in the field of glass ceramics has been done on the electrical and thermal properties. However, few investigations have been reported on the high-permittivity glass ceramics containing PbTiO 3. Kokubo and Tashiro [6] have reported the studies on glassforming regions, dielectric properties, and the spontaneous distortion in crystal grains of transparent glass ceramics based on PbTiO 3. These glasses got crystallization when subjected to heat treatment between 62 C and 74 C. Mandal et al. [7] have studied the dielectric properties in the glass and glass ceramics in BaO PbO TiO 2 B 2 O 3 SiO 2 system. They have reported that the dielectric constant was in the range 15 25 at room temperature (RT) and 1 khz. The lead titanate-based glass ceramics containing B 2 O 3 are vulnerable to moisture, and the problem can be addressed by the addition of SiO 2. Hence, the present work is aimed at the study of synthesis and characterization of PbTiO 3 glass ceramics, containing SiO 2. 2. Experimental Glasses with composition 5PbO : 25TiO 2 : (25-X)B 2 O 3 : XSiO 2 (where X =, 1.5, 2.5, 3.5, and 5 mol%) were prepared from high purity ingredients. The raw materials taken in appropriate proportions were mixed thoroughly and heated in alumina crucibles up to a temperature 4 C above the melting point which was in the range 1 Cto 1 C. The melt was homogenized by stirring and then quenched into aluminium mould at room temperature. The resultant glass samples were annealed at 38 C for 3 hours to remove residual stresses. The glass transition temperature (T g ) and crystallization temperature (T c )for all the glass samples were determined from DTA (Perkin Elmer). To develop the crystalline phases, the glass samples were subjected to two-stage heat treatment schedule. For this purpose, the temperatures (49 C and 52 C) were

2 ISRN Ceramics considered. Keeping the temperatures fixed at 49 Cand 52 C all the glass samples were heat treated for 28 hrs (14 h nucleation + 14 h crystallization). The density of glass and glass-ceramics was measured by Archimedes principle with toluene as an immersion liquid. The coefficient of thermal expansion (CTE) of glass and glass-ceramic samples was measured using Orton dilatometer. The dielectric constant of glass and glass-ceramic samples was measured as a function of temperature at different frequencies using highresolution dielectric analyser (Novocontrol system). The microstructure analysis was carried out by scanning electron microscope (JSM-76F). The XRDs of glass and glassceramics were recorded with Xpert PANalytical diffractometer. The ferroelectric hysteresis loop measurements were performed using Automatic PE Loop Tracer (MARINE INDIA). The values of remnant polarization (P r ) and coercive field (E c ) were determined from the hysteresis loop. 3. Results and Discussion The density, CTE of glass and glass-ceramics, and T g values have been tabulated in Table 1. The density of glassceramic samples was observed to be higher than those of corresponding glasses. The variation in density of glass as well as glass-ceramics with SiO 2 content was not much significant. The maximum value of density was obtained for 2.5 mol% SiO 2 containing glass-ceramic sample. This was due to the higher volume fraction of lead titanate phase in glass matrix as confirmed from XRD. The coefficient of thermal expansion (CTE) for glass-ceramic samples had lower value than the corresponding glass samples, which may be attributed to the rigidity of the structure. Similar results have been reported for lead titanate glass-ceramics [8]. The lower values of CTE for glass-ceramics compared to glasses support the density results. Table 1 also shows the T g values for all the glass samples. The variation in T g with the addition of SiO 2 was not much significant. It was observed that the T g values for all the glass samples were less than the curie temperature (T c = 49 C) of lead titanate. This was of great advantage since according to Lynch and Shelby [9], to avoid the crystal clamping in glass-ceramics it was essential that the glass transition temperature (T g ) of the residual glass must be less than that of curie temperature of the ferroelectric crystal. This helps to prevent the large stresses at crystal glass interface. The XRD patterns of a glass and all glass-ceramic samples have been shown in Figure 1. The XRD pattern of the asquenched glass sample showed a broad hump with the absence of any sharp peaks, which confirmed the amorphous nature. All the glass-ceramic samples were found to have lead titanate as the major crystalline phase. All the major peaks matched very well with the tetragonal lead titanate phase (JCPDS-78-298). Some low intensity lines were observed which were assigned to the lead borate phase (JCPDS-7-1389). The values of volume fraction of lead titanate phase, average crystallite size for glass-ceramic samples along with 5 SiO 2 1 2 3 4 5 6 7 8 1 2 3 4 5 6 7 8 3.5 SiO 2 2.5 SiO 2 1 2 3 4 5 6 7 8 (c) 1.5 SiO 2 1 2 3 4 5 6 7 8 (d) SiO 2 1 2 3 4 5 6 7 8 (e) 6 Glass 5 4 3 2 1 1 2 3 4 5 6 7 8 (f) Figure 1: XRD patterns of the glass and glass-ceramic samples. the room temperature dielectric constant for glass and glassceramics samples have been tabulated in Table 2.The volume fraction of lead titanate crystalline phase was calculated by comparison of integral intensities from X-ray diffraction patterns of amorphous and completely crystalline samples as per the method reported by Ilinsky et al. [1]. The volume

ISRN Ceramics 3 Dielectric constant 25 15 5 25 75 125 175 225 275 325 375 1.5 2.5 Temperature ( C) 3.5 5 Dielectric loss (Tan delta).5.4.3.2.1 25 75 125 175 225 275 325 375 1.5 2.5 Temperature ( C) 3.5 5 Figure 2: Variation of dielectric constant with temperature at 1 khz for glass-ceramic samples. Variation of dielectric loss (Tan delta) with temperature at 1 khz for glass-ceramic samples. SiO 2 (mol %) Table 1: Density and CTE for glass and glass-ceramic samples along with T g values for glasses. Density of glass (g/cm 3 ) Density of glass ceramic (g/cm 3 ) CTE for glass (1 6 /K) CTE for glass ceramics (1 6 /K) 5.67 6.2 9.13 6.23 43 1.5 5.73 6.9 8.7 6.13 43 2.5 5.76 6.14 8.89 5.6 443 3.5 5.8 6.8 9.54 5.42 446 5 5.81 6.12 8.15 4.84 449 T g ( C) fraction of the PbTiO 3 in 2.5 mol% SiO 2 containing glassceramic sample was found to be 57.47%. The average particle size was calculated using Scherrer s formula, which was observed to be in the range of 57 69 nm, for all the glassceramic samples. The room temperature dielectric constant of glassceramic samples was higher than those of corresponding glasses. The values of room temperature dielectric constant for glass and glass-ceramics were observed to be in the range of 51 66 and 71 143, respectively. The glass-ceramic sample with 2.5 mol% SiO 2 has shown maximum value of dielectric constant which may be due to the formation of optimum perovskite lead titanate phase in the glass-ceramics as confirmed from XRD. The variation of dielectric constant and dielectric loss (Tanδ) as a function of temperature for glass-ceramic samples has been depicted in Figures 2 and 2, respectively. The dielectric constant was observed to be nearly constant up to C and showed sudden increase beyond this temperature. Similar variation was observed for dielectric loss. This may be attributed to space charge polarization [8]. The SEM micrographs for glass-ceramic samples have been shown in Figures 3, 3, 3(c), 3(d), and 3(e). The SEM images of, 1.5, and 2.5 mol% SiO 2 containing glass-ceramic samples showed the presence of fine rounded crystals of PbTiO 3 surrounded by the residual glass phase. The average crystallite size was found to be highest for glassceramic sample containing 2.5 mol% SiO 2, which supported the dielectric constant and volume fraction results. SEM images for 3.5 and 5 mol% SiO 2 containing glass-ceramic samples revealed the presence of voids and cracks, which may be responsible for the decrease in dielectric constant. Thus it is observed that the value of dielectric constant of glass ceramics is governed by the volume fraction of PbTiO 3 crystallized and the average particle size. Due to the presence of fine PbTiO 3 crystallites in the glass-ceramic samples as confirmed from XRD and SEM results, the ferroelectric studies of these samples were carried out. The representative hysteresis loops for and 2.5 mol% SiO 2 added to glass-ceramic samples are shown in Figures 4 and 4, respectively. The saturated loops were observed for these samples. This can be understood on the basis of presence of PbTiO 3 crystals in the glass-ceramic samples. The values of P r and E c at room temperature have been tabulated in Table 3. These are preliminary results, and further enhancement in the values of P r and E c can be obtained by optimizing the processing parameters of the glass ceramics.

4 ISRN Ceramics (c) (d) (e) Figure 3: SEM of glass-ceramic samples: mol% SiO2, 1.5 mol% SiO2, (c) 2.5 mol% SiO2, (d) 3.5 mol% SiO2, and (e) 5 mol% SiO2. Table 2: Volume fraction of PbTiO3, average particle size, and RT dielectric constant for glass and glass ceramics. SiO2 (mol %) 1.5 2.5 3.5 5 Volume fraction of PbTiO3 Average particle size (nm) 55.64 52.26 57.47 4.58 44.78 69.57 69.44 69.57 57.53 58.69 RT dielectric constant of glasses at 1 khz 66 51 54 65 6 RT dielectric constant of glass ceramics at 1 khz 12 86 143 71 87

ISRN Ceramics 5.4 SiO 2 1 2.5 SiO 2 Pr (μc/cm 2 ).3.2.1 Pr (μc/cm 2 ).8.6.4.2 3 2 1 1 2 3.1 E (kv/cm).2.3.4 1.5 1.5.5 1 1.5.2 E (kv/cm).4.6.8 1 Figure 4: Hysteresis loops for glass-ceramic samples: mol% SiO 2 and 2.5 mol% SiO 2. Table 3: Remnant polarization (P r ) and coercive field (E c ) for glassceramics samples. SiO 2 (mol %) P r (μc/cm 2 ) E c (kv/cm).32.85 1.5.31 1.92 2.5.79.81 3.5.3 7.17 5.4 7.16 4. Conclusion From the present study it can be concluded that the glassceramic sample with 2.5 mol% SiO 2 exhibited optimum density, dielectric constant, and remnant polarization in the entire series. This sample has a potential for developing it further for practical applications. The dielectric constant of the glass-ceramics is governed by the volume fraction of PbTiO 3 crystallized in them. Acknowledgments The authors wish to thank Indira Gandhi Centre for Atomic Research (IGCAR) Kalpakkam for providing the financial support for research work. One of the authors (V. U. Rahangdale) is thankful to Visvesvaraya National Institute of Technology, Nagpur for providing the Ph. D. fellowship. ceramics, Non-Crystalline Solids, vol. 356, no. 25 27, pp. 1267 1271, 21. [4] A. Herczog, Barrier layers in semiconducting barium titanate glass ceramics, the American Ceramic Society, vol. 67, no. 7, pp. 484 49, 1984. [5] C.G.Bergeron,Crystallization of perovskite lead titanate from glass [Ph.D. thesis], University of Illinois, Urbana, Ill, USA, 1961. [6] T. Kokubo and M. Tashiro, Dielectric properties of finegrained PbTiO 3 crystals precipitated in a glass, Non-Crystalline Solids, vol. 13, no. 2, pp. 328 34, 1974. [7]R.K.Mandal,C.D.Prasad,O.M.Parkash,andD.Kumar, Dielectric behaviour of glasses and glass ceramics in the system BaO-PbO-TiO 2 -B 2 O 3 -SiO 2, Bulletin of Materials Science, vol. 9, no. 4, pp. 255 262, 1987. [8] J. Shankar and V. K. Deshpande, Electrical and thermal properties of lead titanate glass ceramics, Physica B, vol. 46, no. 3, pp. 588 592, 211. [9] S. M. Lynch and J. E. Shelby, Crystal clamping in lead tianate glass ceramics, the American Ceramic Society, vol. 67, no. 6, pp. 424 427, 1984. [1] A. G. Ilinsky, V. V. Maslov, V. K. Nozenko, and A. P. Braovko, Evaluation of the degree of crystallisation in glass ceramics by density measurements, Materials Science, vol. 35, pp. 4495 45,. References [1] B. Jaffe, Piezoelectric Ceramics, Academic Press, London, UK, 3rd edition, 1971. [2] J. J. Shyu and Y. S. Yang, Crystallization and properties of a perovskite glass-ceramic, Materials Science, vol. 31, no. 18, pp. 4859 4863, 1996. [3] M. Rada, V. Maties, S. Rada, and E. Culea, Novel layered structures in lead-vanadate-tellurate unconventional glass

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