Using lithium glass infiltration to enhance the properties of alumina bodies

Acchar, Wilson; Queiroz, José Renato Cavalcanti de

doi:10.1590/S1516-14392008000400010

Abstract

The use of an infiltration process to improve the properties of sintered materials has been widely investigated. This work describes the research carried out in the manufacturing of lithium glass-infiltrated alumina. The infiltration material consisted of a mixture of elements such as Li2O, ZrO2, SiO2 Al2O3, CaO and La2O3. Alumina specimens were sintered in air at 1400 °C for 2 hours. A number of samples were then submitted to the infiltration process at 1400 °C for 15 minutes. Sintered and infiltrated specimens were characterized by X ray diffraction, apparent density, open porosity, flexural strengths and scanning electron microscopy. The results showed that the infiltration process considerably improves the properties of alumina bodies.

glass infiltration; mechanical properties and lithium glass material

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Using lithium glass infiltration to enhance the properties of alumina bodies

Wilson Acchar^* * e-mail: wilson.acchar@pq.cnpq.br ; José Renato Cavalcanti de Queiroz

Programa de Pós-graduação em Ciência e Engenharia de Materiais, Universidade Federal do Rio Grande do Norte - UFRN Bairro Lagoa Nova, 59072-970 Natal - RN, Brazil

ABSTRACT

The use of an infiltration process to improve the properties of sintered materials has been widely investigated. This work describes the research carried out in the manufacturing of lithium glass-infiltrated alumina. The infiltration material consisted of a mixture of elements such as Li₂O, ZrO₂, SiO₂ Al₂O_3, CaO and La₂O₃. Alumina specimens were sintered in air at 1400 °C for 2 hours. A number of samples were then submitted to the infiltration process at 1400 °C for 15 minutes. Sintered and infiltrated specimens were characterized by X ray diffraction, apparent density, open porosity, flexural strengths and scanning electron microscopy. The results showed that the infiltration process considerably improves the properties of alumina bodies.

Keywords: glass infiltration, mechanical properties and lithium glass material

1. Introduction

The sintering stage is the most important phase in the manufacturing process of any ceramic material, mainly where energy costs are concerned. It is well known that the sintering process of alumina and other ceramic materials can be improved by using finer particles (nanotechnology), particles with higher reactivity and sintering additives^1-3. An alternative method that has been investigated to achieve a dense material is the use of an infiltration process in a porous ceramic^4-8. The most commonly used technique to obtain a porous ceramic involves sintering the material until incomplete densification (low or insufficient sintering temperature). The glass infiltration technique can improve the mechanical properties of the alumina material owing to the increase in density of the ceramic material, the generation of compressive residual stress on the surface and the blunting of fine surface cracks produced by the sintering and machining process³. Positive capillary pressure, which occurs when a molten glass material comes into contact with a solid ceramic, is responsible for pressureless infiltration. A number of researchers have also observed the positive effect of the infiltration of metallic elements or alloys such as Si, Al, Al/Si, Al/Mg in a porous material^9-11. Another interesting technique to obtain full interpenetrating networks at low porosities is the use of a slip-cast ceramic suspension in polymeric foam. This method consists of the impregnation of a polymeric foam with a ceramic slurry followed by a burnout of the organic material and the sintering of the ceramic skeleton. The resulting material is a negative replica of the foam with fully open porosity^5,12,13. The composite materials obtained by this technique have low shrinkage, good properties and homogeneous microstructure^6,7. Alumina-glass materials obtained by the infiltration process have been widely studied in recent decades^3-8. This class of materials is characterized by low shrinkage, good mechanical properties and homogeneous structure⁶, making it ideal for studying the potential use of new glass material. As a consequence of the different requirements, different glass ceramic systems such as SiO₂-CaO-Na₂O-P₂O₅, SiO₂-CaO-MgO-P₂O₅-F, SiO₂-Al₂O₃-MgO-CaO-Na₂O-K₂O-P₂O₅-F, SiO₂-CaO-P₂O₅, SiO₂-Al₂O₃-MgO-K₂O-ZrO₂-CeO₂ and the lanthanum borosilicate system have been investigated^6,14. Another recent work has indicated the enhancing effect of borosilicate glass on the tribological properties of alumina⁴. A sintered glass material belonging to the Li₂O-ZrO₂-SiO₂-Al₂O₃ (LZSA) system has recently been investigated using an extrusion process and the replication method^15,16. This lithium glass ceramic material (LZSA) has shown high thermal shock strength and a low thermal expansion coefficient¹⁵, making its use ideal for a number of applications such as cylindrical pieces for pass wire in the textile industry, industrial filtration processes for particulate matter removal, dust and smoke and gas fumes up to 600 °C^15,16. These results suggest that this glass system has good potential and should be further investigated, especially owing to its low cost and low sintering temperature. Studies on the use of lithium-based glass material for infiltration processes are still scarce. The aim of this study was to investigate the prospective use of the infiltration of a glass material consisting of LZSA with additions of CaO and La₂O₃ into alumina bodies.

2. Experimental Procedure

2.1. Alumina ceramic preparation

Alumina APC-2011 (Alcoa, Brazil) with an average grain size of 2.3 µm was used as the ceramic matrix. A glass composition belonging to the Li₂O-ZrO₂-SiO₂-Al₂O₃ system with additions of 15 wt.(%) CaO or La₂O₃ was prepared from commercially available raw materials. Details of LZSA preparation were described in a previous work¹⁷. CaO and La₂O₃ were added to the LZSA to promote better penetration of the molten glass into the porous ceramic matrix. The alumina powder was uniaxially pressed into prismatic bars (30 x 5 x 5 mm³) under a load of 20 MPa. Powder compact was pressureless sintered at 1400 ºC for 2 hours in a tubular furnace.

2.2. Infiltration technique

A glass layer was applied to the surface of the sintered material. The infiltrated materials were then heated in a vacuum oven at 1400 ºC for 15 minutes, where the material melted and penetrated into the porous sample. This infiltration process was repeated twice. The sample was inverted and a second glass layer was applied to the other side. The physical properties of the investigated materials were determined after the sintering process and after the first and second infiltration steps.

2.3. Characterization of the sintered and infiltrate materials

The apparent density and porosity of the sintered and infiltrated materials were determined using Archimedes's water displacement method, as specified by European Standard EN 99 (ISO 10545-3, 1991)¹⁸. Crystalline phases were identified by X ray diffraction (Schimadzu XRD-600) with angles ranging between 15 and 80º with a scanning rate of 2º per minute. The mechanical strength of both materials was determined from the average of five measurements for each case, using a universal testing machine (Zwick-Roell) in a four point bending geometry, with an upper and bottom knife span of 20 and 10 mm, respectively, at a constant cross-head speed of 0.4 mm/min. The microstructure of the samples before and after infiltration was studied by scanning electron microscopy (Philips XL-30) to determine infiltration efficiency.

3. Results and Discussion

Figure 1 shows the X ray diffraction patterns of all the investigated materials. Figure 1a shows that the LZSA glass material exhibits amorphous behavior, with no well-defined crystalline peaks. This amorphous nature is characteristic of the glassy state. As expected, the noninfiltrated sintered alumina shows only the presence of the Al₂O₃ crystalline phase (Figure 1b). Both infiltrated materials (LZSA+CaO and LZSA+La₂O₃) show the presence of Al₂O₃, ZrO₂, LiAlSi₂O₆ and LiSiO₃ (Figure 1c and 1d), which is in agreement with other studies^14,15. The addition of CaO or La₂O₃ had no effect on the X ray diffraction pattern. No other crystalline phases were identified. Figure 2 shows porosity values as a function of the infiltration step. It is clear that the infiltration process caused a significant decrease in open porosity, regardless of the presence of CaO or La₂O₃. The infiltration of the glass material by capillary forces caused a filling of the internal pores, leading to a decrease in porosity from 40 to 30% in the first infiltration and to 10% in the second infiltration.

Table 1 summarizes the properties obtained in this work. As can be seen the infiltrated materials have higher strength values than those of uninfiltrated ceramic bodies

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The second infiltration caused a marked increase in strength values (~210 MPa) compared to the pure alumina (24 MPa). This may be associated to surface defect healing of the specimens. These results confirm the positive effect of LZSA glass infiltration. Published studies also describe the positive effect of the infiltration of different glass systems on the strength and fracture toughness of alumina bodies^4,7 and polymer composites⁵. It is well known that mechanical behavior is dependent on factors such as grain size, crystalline content and sample size. Given that the samples described in the literature were significantly smaller (20 x 1.2 x 4 mm³) than those used in this study, the resulting strength values were higher. SEM images of the lithium glass alumina material after infiltration are shown in Figure 3. Figures 3a and 3b compare microstructural aspects of the infiltrated and noninfiltrated specimens. Microscopy shows marked differences between the two materials. Compared to the noninfiltrated sample, the microstructure of the lithium glass phase region seems to have smaller pores uniformly distributed in the matrix and a lower presence of voids, which is characteristic of an incomplete sintering process.

Figure 3c shows the difference between the infiltrated and noninfiltrated area in the same sample (Figure 3c). The infiltrated region shows a more homogeneous and denser region, which is characteristic of a pronounced filling of the pores produced by the infiltration of the glass phase. The noninfiltrated area has a lower densification level and is characterized by non- penetration of the glass phase. This result confirms that the lithium glass investigated in this work penetrated into the porous alumina, filling the pores and contributing to the increase in alumina matrix properties. Figure 3d shows the fracture surface of the glass-infiltrated material. It can be seen that the fracture mode is predominantly transgranular. The microstructure also shows smaller pores homogeneously distributed in the matrix.

4. Conclusions

Pressureless infiltration of Al₂O₃ performed with a lithium glass allowed us to obtain dense samples at low temperatures with good properties. Glass infiltration significantly improved the density, open porosity and bending strength of the alumina, showing that the LZSA glass system warrants further investigation. The beneficial effect produced by glass infiltration may be attributed to the healing of defects obtained by glass flow.

Received: June 6, 2008

Revised: November 3, 2008

1. Dorre E, Huebner H. Alumina: Processing and Applications. Berlin: Springer; 1984.
2. Acchar W, Ramalho EG, Hotza D, Segadaes AM. Using granite rejects to aid densification and improve mechanical properties of alumina bodies. Journal Materials Science 2005; 40 (15):3905-3909.
3. Guazzato M, Albakry M, Quach L, Swain MV. Influence of surface and heat treatments on the flexural strength of a glass-infiltrated alumina/zirconia-reinforced dental ceramic. Dental Materials 2005; 21 (5):454 463.
4. Sarkar D, Basu B, Chu MC, Cho SJ. In glass infiltration beneficial to improve fretting wear properties for alumina. Journal of American Ceramic Society 2007; 90 (2):523-530.
5. Peitl O, Orefice RL, Hench LL, Brennan AB. Effect of the cystalization of bioactive glass reinforcing agents on the mechanical properties of polymer composites. Materials Science & Engineering 2004; A372 (1-2):245-251.
6. Sheng XJ, Xu H, Jin ZH, Wang YL. Preparation of glass-infiltrated 3Y-TZP/Al2O3/glass composites. Materials Letters 2004; 58 (11):1750 1753.
7. Guazzato M, Albakry M, Ringer SP. Strength, fracture toughness and microstructure of a selection of al-ceramic materials. Part I. Pressable and alumina glass-infiltrated ceramics. Dental Materials 2004; 20 (5):441 448.
8. Mattern A, Huchler B, Staudenecker D, Oberacker R, Nagel A, Hoffmann MJ. Preparation of interpenetrating ceramic-metal composites. Journal European Ceramic Society 2004; 24 (12):3399-3408.
9. Rao BS, Jayaram V. Pressureless infiltration of Al-Mg based alloys into Al₂O₃ preforms:mechanisms and phenomenology. Acta Materialia 2001; 49 (13):2373-2385.
10. Kevorkijan VM. The reactive infiltration o porous ceramic media by a molten aluminum alloy. Composites Science and Technology 1999; 59 (5):683-686.
11. Travitzky NA, Gutmanas EY, Claussen N. Mechanical properties of Al₂O₃/Si composites fabricated by pressureless infiltration technique. Materials Lettters 1997; 33 (1-2):47-50.
12. Kroll P. Modelling polymer derived ceramics. Journal European Ceramic Society 2005; 25 (2-3):163-174.
13. Michalet T, Parlier M, Beclin F, Duclos R, Crampon J. Elaboration of low shrinkage mullite by active filler controlled pyrolysis of siloxanes. Journal European ceramic Society 2002; 22 (2):143-152.
14. Hoeland W. Biocompatible and bioactive glass-ceramic-state of the art and new directions. Journal Non-Crystalline Solids 1997; 219 (1):192-197.
15. Montedo OR, Reitz GM, Bertan FM, Oliveira APN. Extruted LZS glass-ceramics. American Ceramic Society Bulletin 2004; 83:9201-9206.
16. Sousa, E.; Silveira, C. B.; Fey, T.; Greil, P.; Hotza, D.; de Oliveira, A. P. LZSA glass ceramic foams prepared by replication process. Adances in Applied Ceramic 2005; 104(1):22-29.
17. Renato J. Estudo de sistemas vítreos para infiltração em alumina. [Dissertation, Pos-graduation Program of Science and Materials engineering]. Rio Grande do Norte: Federal University of Rio Grande do Norte; 2007.
¹⁸
INTERNATIONAL ORGANIZATION FOR STANDARD. ISO 10545-3 (EN 99). Determination of water absorption, apparent porosity, apparent relative density and bulk density of ceramic tiles. Genebra; 1991.

*

e-mail:

wilson.acchar@pq.cnpq.br

Publication Dates

Publication in this collection
11 Feb 2009
Date of issue
Dec 2008

History

Accepted
03 Nov 2008
Received
06 June 2008

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

[1] 1. Dorre E, Huebner H. Alumina: Processing and Applications. Berlin: Springer; 1984.

[2] 2. Acchar W, Ramalho EG, Hotza D, Segadaes AM. Using granite rejects to aid densification and improve mechanical properties of alumina bodies. Journal Materials Science 2005; 40 (15):3905-3909.

[3] 3. Guazzato M, Albakry M, Quach L, Swain MV. Influence of surface and heat treatments on the flexural strength of a glass-infiltrated alumina/zirconia-reinforced dental ceramic. Dental Materials 2005; 21 (5):454 463.

[4] 4. Sarkar D, Basu B, Chu MC, Cho SJ. In glass infiltration beneficial to improve fretting wear properties for alumina. Journal of American Ceramic Society 2007; 90 (2):523-530.

[5] 5. Peitl O, Orefice RL, Hench LL, Brennan AB. Effect of the cystalization of bioactive glass reinforcing agents on the mechanical properties of polymer composites. Materials Science & Engineering 2004; A372 (1-2):245-251.

[6] 6. Sheng XJ, Xu H, Jin ZH, Wang YL. Preparation of glass-infiltrated 3Y-TZP/Al2O3/glass composites. Materials Letters 2004; 58 (11):1750 1753.

[7] 7. Guazzato M, Albakry M, Ringer SP. Strength, fracture toughness and microstructure of a selection of al-ceramic materials. Part I. Pressable and alumina glass-infiltrated ceramics. Dental Materials 2004; 20 (5):441 448.

[8] 8. Mattern A, Huchler B, Staudenecker D, Oberacker R, Nagel A, Hoffmann MJ. Preparation of interpenetrating ceramic-metal composites. Journal European Ceramic Society 2004; 24 (12):3399-3408.

[9] 9. Rao BS, Jayaram V. Pressureless infiltration of Al-Mg based alloys into Al₂O₃ preforms:mechanisms and phenomenology. Acta Materialia 2001; 49 (13):2373-2385.

[10] 10. Kevorkijan VM. The reactive infiltration o porous ceramic media by a molten aluminum alloy. Composites Science and Technology 1999; 59 (5):683-686.

[11] 11. Travitzky NA, Gutmanas EY, Claussen N. Mechanical properties of Al₂O₃/Si composites fabricated by pressureless infiltration technique. Materials Lettters 1997; 33 (1-2):47-50.

[12] 12. Kroll P. Modelling polymer derived ceramics. Journal European Ceramic Society 2005; 25 (2-3):163-174.

[13] 13. Michalet T, Parlier M, Beclin F, Duclos R, Crampon J. Elaboration of low shrinkage mullite by active filler controlled pyrolysis of siloxanes. Journal European ceramic Society 2002; 22 (2):143-152.

[14] 14. Hoeland W. Biocompatible and bioactive glass-ceramic-state of the art and new directions. Journal Non-Crystalline Solids 1997; 219 (1):192-197.

[15] 15. Montedo OR, Reitz GM, Bertan FM, Oliveira APN. Extruted LZS glass-ceramics. American Ceramic Society Bulletin 2004; 83:9201-9206.

[16] 16. Sousa, E.; Silveira, C. B.; Fey, T.; Greil, P.; Hotza, D.; de Oliveira, A. P. LZSA glass ceramic foams prepared by replication process. Adances in Applied Ceramic 2005; 104(1):22-29.

[17] 17. Renato J. Estudo de sistemas vítreos para infiltração em alumina. [Dissertation, Pos-graduation Program of Science and Materials engineering]. Rio Grande do Norte: Federal University of Rio Grande do Norte; 2007.

[18] ¹⁸
INTERNATIONAL ORGANIZATION FOR STANDARD. ISO 10545-3 (EN 99). Determination of water absorption, apparent porosity, apparent relative density and bulk density of ceramic tiles. Genebra; 1991.

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Using lithium glass infiltration to enhance the properties of alumina bodies

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