期刊文献+

刚玉-莫来石-锌铝尖晶石复相材料的合成与烧结 被引量:21

SYNTHESIS AND SINTERABILITY OF CORUNDUMMULLITEZnO·Al_(2)O_(3 ) MULTIPHASE MATERIALS
下载PDF
导出
摘要 热力学计算表明:在Al2O3SiO2ZnO三元体系中,硅酸锌(Zn2SiO4)和锌铝尖晶石(ZnAl2O4)生成Gibbs自由能在温度为1326.85℃以下是负值,莫来石(3Al2O3·2SiO2)的Gibbs生成自由能在温度为426.85℃以上是负值。系统中Al2O3富存的条件下,Al2O3可与Zn2SiO4反应生成锌铝尖晶石。以ZnO,SiO2,Al(OH)3为原料,通过固相反应合成刚玉莫来石锌铝尖晶石复相材料。研究烧结温度和气氛对刚玉莫来石锌铝尖晶石复相材料的合成与烧结性能的影响。用X射线衍射分析复相材料中的物相成分。用扫描电子显微镜观察复相材料的显微结构。结果发现:Al2O3SiO2ZnO三元体系在所选择的配料点,1300℃及1600℃时均能生成刚玉、莫来石、锌铝尖晶石3种物相,不会出现低熔点的硅酸盐相,这明显区别于Al2O3MgOSiO2三元体系,该体系在1500℃左右会出现低熔点相。试样在900℃烧成后出现锌铝尖晶石相。随着温度升高,试样的致密化过程加快,部分抵消了1300℃左右莫来石形成所产生的体积膨胀。当烧结温度高于1300℃时,试样的致密化过程大大加快。还原性气氛不利于刚玉莫来石锌铝尖晶石复相材料的合成与烧结。 Thermodynamics analysis indicates that in Al_2O_(3)SiO_2ZnO ternary system, Gibbs free energies of Zn_2SiO_(4) and ZnAl_2O_(4) are all negative under the temperature of 1 326.85 ℃ and the Gibbs free energy of mullite (3Al_2O_(3)·2SiO_(2)) is negative only above the temperature of 426.85 ℃. Al_2O_(3) can be reacted with Zn_2SiO_(4) to form ZnAl_2O_(4) if Al_2O_(3) content is rich (enough) in the system. The analysis proved that using ZnO, SiO_(2) and Al(OH)_(3) as raw materials corundummulliteZnO ·(Al_2O_3) multiphase materials were synthesized by the solid-state reaction. Effects of sintering temperatures and atmosphere on the synthesis and sintering properties of the multiphase materials were studied. The mineral phase was characterized by X-ray diffraction (XRD) and the microstructure of corundummulliteZnO ·Al_(2)O_(3) multiphase materials was observed by scanning electron microscope (SEM). Results show the distinction between the ternary system of Al_2O_(3)SiO_(2)ZnO and (Al_(2)O_(3))MgOSiO_(2). Namely, in the former ternary system there is no low melt silicate phase found but corundum, mullite and ZnO·Al_(2)O_(3) are formed above 1 300 ℃ and 1 600 ℃ under the proper condition. However, low melt phase is found in Al_(2)O_(3)MgOSiO_(2)system at about 1 500 ℃.ZnO·Al_(2)O_(3)is formed at about 900 ℃. With the increase of the temperature, the densification process is accelerated, which can partially counteract the bulk expansion from mullite solid-state reaction at about (1 300 ℃). As the sintering temperature is above 1 300 ℃, the densification process is accelerated dramatically. The reducing atmosphere is unfavorable for the synthesis and sinterability of corundummulliteZnO·Al_(2)O_(3) multiphase materials.
出处 《硅酸盐学报》 EI CAS CSCD 北大核心 2005年第1期7-11,共5页 Journal of The Chinese Ceramic Society
基金 湖北省自然科学基金(2002AB071) 湖北省重点实验室开放基金资助项目。
关键词 热力学 锌铝尖晶石 复相材料 合成 烧结 thermodynamics gahnite multiphase material synthesis sinterability
  • 相关文献

参考文献10

  • 1李联生,项长祥,赵沛,王长华,田红燕,李士琦.熔体过滤法钢液脱铜的研究[J].钢铁研究学报,1998,10(3):5-7. 被引量:10
  • 2朱伯铨,李享成.Al(OH)_3和ZnO合成锌铝尖晶石反应动力学的研究[J].硅酸盐学报,2003,31(12):1171-1174. 被引量:8
  • 3ESCARDINO A, AMOROS J L, GOZALBO A, et al. Gahnite devitrification in ceramic frits, mechanism and process kinetics [J]. J Am Ceram Soc, 2000, 83(12) :2 938- 2 944.
  • 4PANDEY R, GALE J D, SAMPATH S K,et al. Atomistic simulation study of spinel oxides, zinc aluminate and zinc gallate[J]. J Am Ceram Soc, 1999, 82(12):3 337-3 341.
  • 5KASHII N, MAEKAWA H, HINATSU Y. Dynamics of the cation mixing of MgAl2O4 and ZnAl2O4 spinel[J]. J Am Ceram Soc, 1999, 82(7):1 844-1 848.
  • 6JESCHKE P, MORTL G. Recent tendencies in refractories for iron and steel production[A]. United International Technical Conference on Refractories(UNITECR)[C].San Paulo, Brazil, 1993. 26 -75.
  • 7LEVIN E, ROBBINS C R. Phase Diagrams for Ceramists[M].Columbus Ohio: American Ceramic Society, 1964. 258.
  • 8ROLSETH S, STOEN L, THONSTAD J. The solubility of ZnO and ZnAl2O4 in cryolite melts[J]. Metall Mater Trans B, 1997, 28:1 099-1 101.
  • 9TAKEUCHI N, TAKAHASHI H, ISHIDA S. Mechanistic study of solid-state reaction between kaolinite and ferrous oxide at high temperatures[J].J Ceram Soc Jpn, 2000. 108(10):876 - 861.
  • 10BRANSON D L. Kinetics and mechanism of the reaction between zinc oxide and aluminum oxide[J].J Am Ceram Soc,1965, 48(11): 591-595.

二级参考文献14

  • 1李联生,冶金物理化学论文集,1997年,127页
  • 2李文超,冶金热力学,1995年,249页
  • 3Li J G,J Mater Sci Lett,1992年,11卷,903页
  • 4ESCARDINO A, AMOROS J L, GOZALBO A, et al. Gahnite devitrification in ceramic frits: mechanism and process kinetics[J]. J Am Ceram Soc, 2000, 83(12):2 938-2 944.
  • 5GRABOWSKA H, MISTA W, TTAWCZYN J, et al. Catalytic alkylation of phenol with over zinc[J]. Res Chem Intermed, 2001, 27(3):305-313.
  • 6JESCHKE P, MORTL G. Recent tendencies in refractories for iron and steel production[A]. Unitied Znternational Technical Conference on Refractories (UNITECR 93′)[C], Sao Paulo, Brazil, 1993.
  • 7顾学民,龚毅生, 藏希文,等.无机化学丛书[M].第二版.科学出版社, 1998.GU Xueming , GONG Yisheng,ZANG Xiwen, et al. Inorganic Chemistry Collection(in Chinese). Beijing: Science Press, 1998.
  • 8OZAWA T. A new method of analyzing thermogravimetric data[J]. Bull Chem Soc Jpn, 1965, 38(11):1 881-1 886.
  • 9YANG Zhangquan, HU Rongzu, XIE Yi. A new method to estimate kinetic parameters from a single non-isothermal DSC curve[J]. Thermochim Acta, 1992, 195:157-162.
  • 10CHU T-M G C, HALLORAN J W. Curing of highly loaded ceramic suspensions in acrylates[J]. J Am Ceram Soc, 2000, 83(10): 2 375-2 380.

共引文献13

同被引文献219

引证文献21

二级引证文献126

相关作者

内容加载中请稍等...

相关机构

内容加载中请稍等...

相关主题

内容加载中请稍等...

浏览历史

内容加载中请稍等...
;
使用帮助 返回顶部