冲击波处理的AlN粉体的低温烧结特性

无机材料学报, 1998, 13(2): 229-233.

冲击波处理的AlN粉体的低温烧结特性

吴音 , 周和平 , 缪卫国 , 韩巍 , 薛鸿陆

清华大学材料系新型陶瓷与精细工艺国家重点实验室

北京100084

长沙410073>

Departemnt of Materials Science and Engineering

Tsinghua University Beijing 100084 China

+Department of Applied Physics

National University of Defense Technology Changsha 410073 Chi>

关键词： AlN陶瓷 , null , null , null , null

Characteristics of Low-Temperature Sintering of Shocked Aluminium Nitride Powder

WU Yin , ZHOU Her-Ping , MIAO Wei-Guo , HAN Wei , XUE Hong-Lu

Keywords： AlN, low-temperature sintering, shock waves treatment, dislocation, microstrain , 低温烧结 , 冲击处理 , 位错 , 晶粒畸变

利用X射线衍射仪，对冲击波（压力为9．SGPa）处理的AIN粉体的衍射峰展宽现象进行分析，得到粉体内平均微观应变为2．85×10^-3；相应的位错密度为10¹¹／cm²；体内储存的缺陷能为0．36Cal／g．研究了以冲击波处理的AIN粉体为原料，在添加6Wt％以Dy₂O₃为主的助烧结剂的低温无压烧结过程中，缺陷对低温烧结和热导率的影响．结果表明：冲击波处理AIN粉体所致缺陷能，除了可以促进烧结；同时还起到了去除AIN晶格中的Al₂O₃，及提高热导率的作用．粉体中储存的能量在烧结过程中释放，使冲击粉试样比未冲击粉试样达到最大线收缩速率时的温度降低25℃；试样在1610℃，无压烧结4h，冲击粉试样密度为理论值的98％，而未冲击试样仅为80％．位错在烧结过程中为氧扩散提供渠道，使氧的扩散除了通过溶解一析出过程，还有固态扩散的作用，而这些位错在烧结后期得到回复．

AlN powder was treated by shock waves with pressure of 9.8GPa. X-ray line broadening effect was found as the result of strain stored in shocked AlN lattice. Estimated
value of the strain is 2.85×10^-3, related dislocation density in shocked AlN powder is in the order of 10¹¹/cm², the energy stored in shocked
powder is 0.36Cal/g. The low temperature pressureless sintering process and thermal conductivity of shocked AlN powder with 6wt% additives were investigated. The results
showed that, the dislocation in shocked AlN powder can promote low temperature sinetring. In addition, it can remove Al₂O₃ from AlN lattices and achieve high thermal conductivity.
The energy stored in the shocked powder was released during the sintering process. The temperature of maximum shrink rate of shocked sample was about 25℃ lower than
that of unshocked one. The density of the shocked sample sintered at 1610℃ for 4h was 98% of its theoretical value, compared with 80% of the unshocked one. The
dislocation in shocked AlN powder can provide paths for the diffusion of oxygen through the grain in sintering process. So besides dissolution-reprecipitation, dislocation-
enhanced diffusion contributes its efforts to sintering, and it is beneficial for both sintering and achieving high thermal conductivity. The dislocation then can recover
in the later stage of the sintering process.

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