Viscous Flow Sintering of Mica Glass-Ceramic Composite

VISCOUS FLOW SINTERING OF MICA GLASS-CERAMIC COMPOSITE Maziar Montazeriana, Parvin Alizadehb, Bijan Eftekhari Yektac a R&D Center, Apadana Ceram Company, Tehran, Iran b School of Engineering, Tarbiat Modares University, Tehran, Iran c Ceramic Division, Department of Materials, Iran University of Science and Technology, Tehran, Iran Corresponding author: [email protected] (M. Montazerian) Address: No. 7, Houman Alley, North Tavanir Street, Tehran, Iran. ZIP: 1435633381, Tel: (+9821) 88878671, Fax: (+9821) 88878370 ABSTRACT In this study, mica glass-ceramic reinforced with 5, 10 and 15 wt.% partially stabilized zirconia (ZrO2 stabilized with 3 mol% Y2O3) was synthesized via pressureless sintering. Sinterability of composite was investigated in the temperature range of 1060-1170 °C using soaking time of 240 min. The sintered specimens were characterized by Scanning Electron Microscopy (SEM) and X-ray Diffraction (XRD). Mechanical properties of sintered specimens such as three-point bending strength and Vickers micro hardness were also investigated. Microstructural observations revealed that plate-like mica crystals were crystallized in the vicinity of submicron and fine zirconia particles. Strength measurements showed that increasing the amount of zirconia increased the strength from 50.91 ± 10.50 MPa for mica glass-ceramic to 132.47 ± 13.80 MPa for the composite with a content of 15 wt.% ZrO2. The micro hardness of the glass-ceramic was also improved up to 4.35 ± 0.64 GPa. Keywords: Sintering; Glass-Ceramics; Composite; Mechanical Properties. INTRODUCTION Mica glass-ceramics are well-known machinable ceramics, which have excellent thermal, electrical and biological properties. These unique properties of mica glass-ceramics make them suitable for use in high-performance applications such as aerospace industry, insulators, welding tools, biomedical applications, etc. Nevertheless these glass-ceramics suffer from their low hardness and insufficient mechanical strength [1]. Numerous attempts have been made to overcome the mentioned weakness of these materials. Substitution of K+ or Na+ by Ba2+ or Ca2+ ions resulted in the formation of high-strength mica glass-ceramics [2]. Extruded or hot-pressed mica glass-ceramics with orientated structures represent high strength and toughness in comparison with the conventional mica glass-ceramics containing randomly orientated mica crystals with the house of cards structure [3,4]. Furthermore, they could be reinforced with ZrO2, which is crystallized from the bulk glass. It has been reported that calcium mica-based nanocomposite, which contains nano-size (20-50 nm) tetragonal-ZrO2 particles, exhibits high flexural strength and fracture toughness [5]. Previous study revealed that by using an additive such as P2O5, viscous flow sintering can be successfully used to produce mica glass-ceramic with excellent machinability and appropriate final density. Optimum composition obtained from the sintering method was selected as a matrix of composite in this study [6]. In this study, in order to improve mechanical properties, mica glass-ceramic composites reinforced with partially stabilized zirconia particles (Y-PSZ, ZrO2 stabilized with 3 mol% Y2O3) were synthesized by employing pressureless sintering. Additionally, microstructural studies and investigation into the interactions between mica glass and Y-PSZ were the objective of this study. EXPERIMENTAL PROCEDURE The composition of mica-based glass was 40.13 SiO2, 16.24 Al2O3, 19.11 MgO, 8.00 K2O, 2.23 B2O3 , 9.55 F and 4.45 P2O5 wt.%. The raw materials used in the preparation of glass were all high quality reagent-grade chemicals supplied by Merck. The thoroughly mixed glass batch was melted in platinum crucible at 1410 °C for 30 min. The melt was then quenched in the cold distilled water to make a cullet. Then the cullet was milled in a high-speed alumina mill in an ethanol environment for 45 min. The particle size measurement of the glass powder was carried out by a laser particle size analyzer (Fritsch, Analysette 22). The milled glass powder was mixed with 5, 10 and 15 wt.% Y-PSZ powder (Aldrich; submicron powder with mean particle size of 0.89 μm). Wet mixing in ethanol was performed for 6 h in an alumina jar-mill. The dried powder of each sample was granulated by adding 2 wt.% PVA. The granulated powders were pressed using an uniaxial hydraulic press into the discs (10 mm in diameter and 4 mm thickness) at a final pressure of 65 MPa. After the organic binder was removed from the samples by holding at 450 °C for 1 h, the discs were fired between 1060-1170 °C, in an electric furnace. The heating rate was 20 °C/min and the sample remained in the maximum temperature for 240 min. The mica glass-ceramic named as Mica, and the composites containing 5, 10 and 15 wt.% Y-PSZ here-after are referred to as M5Z, M10Z and M15Z, respectively. The bulk density of sintered samples was determined by Archimedes method. The crystallized samples were then subjected to XRD analysis (Siemens D-500, Cu Kα radiation at 40 kV). The microstructural studies were done by scanning electron microscope (SEM, Philips XL30). The content of tetragonal zirconia phase was determined using the method of Garvie and Nicholson [7]. Sintered rectangular bars (2.5 mm × 5 mm × 25 mm) were also used for three-points bending strength with a span of 20 mm. The flexural strength measurement of the glass-ceramic and composites were conducted in air at room temperature (Instron Universal Testing Machine-1196) with a crosshead speed of 1 mm/min. A Vickers micro-hardness tester with a diamond pyramid indenter (Buehler, Micromet I) was used to measure microhardness. The load was 500 g and the loading time was 30 s. RESULTS AND DISCCUSION Mica glass powder had the mean particle size of 12.5 µm. Calculated relative density of green compacted specimens was 56% for glass powder, 54% for M5Z and 51% for M10Z and M15Z. Relative densities of the specimens versus firing temperatures are plotted in Fig. 1. By increasing the temperature, relative density increased to the maximum values and then decreased at higher temperatures. Achieving the maximum density is a criterion for determining the optimum sintering temperatures. Therefore, the temperatures of 1100, 1110, 1120 and 1130 °C were chosen for Mica, M5Z, M10Z and M15Z as the optimum sintering temperature, respectively. Bloating of the samples caused a decrease in the relative densities of them at temperatures higher than the sintering temperatures. Bloating of the specimens can be attributed to the volatilization of silicon tetrafluoride at the final stage of sintering when the open porosities are now closed. XRD patterns of the sintered mica glass-ceramic and composites are shown in Fig. 2. XRD patterns of the sintered mica glass-ceramic and composites are shown in Fig. 2. 0.98 Mica M5Z M10Z M15Z Relative Density 0.96 0.94 0.92 0.9 0.88 0.86 1040 1060 1080 1100 1120 1140 1160 1180 Temperature (°C) Fig. 1. Relative density of fired samples vs. temperature. Fig. 2. XRD patterns of sintered specimens. The sintered glass-ceramic contained fluorophlogopite, forsterite and spinel (MgAl2O4). Besides the mentioned phases, monoclinic zirconia (m-ZrO2), tetragonal zirconia (t-ZrO2) and minor amount of zircon (ZrSiO4) were detected in the composites. The content of t-ZrO2 calculated using Garvie and Nicholson [7] method was 37.6%, 33.6% and 29.6% of the whole content of YPSZ in composites M5Z, M10Z and M15Z, respectively. The as-received Y-PSZ powder contained 80% t-ZrO2, which decreased to about 65% after mixing with glass powder using a jar-mill. This reduction directly resulted from the stress induced transformation of t-ZrO2 to m-ZrO2 during milling. Further decrease in the content of tZrO2 in the fired composites should be due to the transformation of the t-ZrO2 to m-ZrO2 occurred during sintering process. The formation of zircon and especially this transformation have been reported to arise from a reaction between the residual glassy phase and zirconia phase during sintering [8]. This reaction also decreases the alloying effect of Y2O3 on the stability of tZrO2 phase, by formation of a glass composition in the Y2O3-Al2O3-SiO2 system [9]. The SEM images of the sintered specimens etched with 5 wt.% HF solution for 45 s are illustrated in Fig. 3. Microstructure of the Mica contained plate-like mica crystals with conventional interlocking structure (Fig. 3a). In the M5Z and M10Z both fine dispersed particles (~ 0.1 µm) and agglomerated particles of zirconia were observed (Fig. 3b and c). Agglomeration became clearer in the M15Z (Fig. 3d). It seems that during sintering process, Y-PSZ particles began to agglomerate between the glass powders, in order to reduce their free surface energy. Low viscosity of residual glass and surface crystallization of glass particles would enhance the agglomeration of zirconia particles. This behavior is illustrated schematically in Fig. 4. Fig. 3. SEM images of the sintered samples (×5000): (a) Mica, (b) M5Z, (c) M10Z and (d) M15Z. Fig. 4 Schematic illustration of agglomeration during sintering process: (a) Green compact of mica glass and zirconia particles, (b) less dandified structure, and (c) well-dandified body. Mechanical properties as well as relative density of the sintered specimens are summarized in Table 1. All composites had a lower relative density than the mica glass-ceramic (Mica). Micro hardness increased by increasing the content of ZrO2 in the specimens. The M10Z and M15Z represented nearly same values of bending strength, which were the maximum strengths of the composites. Zirconia particles can retard the densification of composites due to i) the dissolution of ZrO2 which causes to increase the viscosity of residual glass and interferes with further densification of composites and ii) induction of a tangential tensile stresses which act opposite of viscous flowing of glass matrix [10]. Table 1 Mechanical properties and relative density of specimens. Sample Vickers micro Hardness (GPa) Mica M5Z M10Z M15Z 2.62 ± 0.36 3.04 ± 0.14 3.83 ± 0.83 4.35 ± 0.64 Bending Strength (MPa) 50.91 ± 10.5 103.31 ± 20.46 131.63 ± 7.77 132.47 ± 13.8 Relative Density (%) 97.2 96.6 94.7 92.4 Several mechanisms such as crack deflection by dispersion strengthening and transformation toughening by existing t-ZrO2 phase can be attributed to the improvement of mechanical strength. Additionally, dissolution of ZrO2 in the residual glass incorporates minor amounts of Zr4+ into the residual glass structure. The presence of Zr ions in the residual glass network, which produce bracing by complex [ZrO4] structural units, may represent another reinforcement mechanism. CONCLUSIONS Mica glass-ceramic composites reinforced with Y-PSZ particles, which have desirable final density and improved mechanical properties, were successfully fabricated via pressureless sintering. The dissolution of Y-PSZ occurred in the residual glass and resulted in the formation of zircon and transformation of t- ZrO2 to m-ZrO2. The leaching of yttrium reduces the alloying effect of Y2O3 on the stability of t-ZrO2, and transformation of t-ZrO2 to m-ZrO2 occurred. REFRENCES [1] W. Höland and G. Beall, Glass-Ceramic Technology, The American Ceramic Society, Westerville, OH, 148-152, 2002. [2] T. Uno, T. Kasuga and K. Nakajima, High-strength mica-containing glass-ceramics, J. Am. Ceram. Soc., 74, 3139-3141, 1991. [3] K. Cheng, J. Wan and K. Liang, Hot-pressed mica glass-ceramics with high strength and toughness, J. Am. Ceram. Soc., 82, 1633-1634, 1999. [4] S. Habelitz, G. Carl and C. Rüssel, Processing, microstructure and mechanical properties of extruded mica glass-ceramics, Mater. Sci. Eng. A, 307, 1-14, 2001. [5] T. Uno, T. Kasuga, S. Nakayama and A.J. Ikushima, Microstructure of mica-based nanocomposite glass-ceramics, J. Am. Ceram. Soc., 76, 539-554, 1993. [6] B. 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