高压烧结致密非晶SiBCN块体陶瓷的组织结构演化与力学性能  被引量：1

作　　者：李达鑫 杨治华[1,2,3] 贾德昌[1,2,3] 蔡德龙[1,2] 段小明[1,2,3] 何培刚[1,2] 王胜金[1,2] 周玉[1,2,3] 田永君[4] LI Daxin;YANG Zhihua;JIA Dechang;CAI Delong;DUAN Xiaoming;HE Peigang;WANG Shengjin;ZHOU Yu;TIAN Yongjun(Institute for Advanced Ceramics,School of Materials Science and Engineering,Harbin Institute of Technology,Harbin 150080,China;Key Laboratory of Advanced Structure-Function Integrated Materials and Green Manufacturing Technology,Harbin Institute of Technology,Harbin 150080,China;State Key Laboratory of Advanced Welding and Joining,Harbin Institute of Technology,Harbin 150001,China;State Key Laboratory of Metastable Materials Science and Technology,Yanshan University,Qinhuangdao 066004,Hebei Province,China)

机构地区：[1]哈尔滨工业大学材料科学与工程学院特种陶瓷研究所,哈尔滨150080 [2]哈尔滨工业大学"先进结构功能一体化材料与绿色制造技术"工业和信息化部重点实验室,哈尔滨150080 [3]哈尔滨工业大学先进焊接与连接国家重点实验室,哈尔滨150001 [4]燕山大学亚稳材料制备技术与科学国家重点实验室,河北秦皇岛066004

出　　处：《自然杂志》2020年第3期157-169,共13页Chinese Journal of Nature

基　　金：funded by the National Postdoctoral Program for Innovative Talents (Grant No. BX20190095);National Key Research and Development Program (Grant No. 2017YFB0310400);Financial support from the National Natural Science Foundation of China (Grant No. 51621091, 51472059);China’s Postdoctoral Science Fund (Grant No. 2019M660072, LBH-Z19141) were also appreciated

摘　　要：非晶SiBCN陶瓷是一类独特的结构材料,具有低比重、高比强度、优异的高温损伤容限等特殊结构和性能,因此在高温防热结构部件上极具应用潜力。通过合理的结构与化学成分协同设计,可探索陶瓷形貌/微观结构演化及断裂行为的基本特征,从而进一步提高其力学性能,以满足实际应用需求。因此,文章以石墨、六方氮化硼、立方硅和硼等元素粉末为原料,提出了采用机械合金化结合高压烧结技术(1 000°C/3~5 GPa/30 min)制备致密非晶Si2ByC2N(y=1.5~4)块体陶瓷的方法。通过XRD、SEM、TEM、TG等表征手段,研究了烧结压力诱导该系非晶陶瓷的组织结构演化、相变及热稳定性,并对其力学性能,特别是断裂行为进行了详细讨论。结果表明,提高烧结压力促使陶瓷基体由完全非晶态向晶态转变,部分块体陶瓷由大量非晶相、少量c-Si和/或t-BN(C)纳米晶相组成,显示出依赖于硼含量的物相组成。高压烧结有效地促进了陶瓷的烧结致密化,导致材料内自由体积的湮灭和"河流状"断裂形貌的产生。随着烧结压力的提高,陶瓷材料的体积密度、纳米硬度和杨氏模量单调增加。在相同烧结条件下,硼含量的增加削弱了非晶Si2ByC2N(y=1.5~4)块体陶瓷的力学性能和热稳定性。1 000°C/5 GPa/30 min烧结制备的致密非晶Si2B1.5C2N块体陶瓷的体积密度、纳米硬度和杨氏模量分别为2.69 g/cm3、33.6±2.2GPa和414.2±16.5 GPa。Amorphous SiBCN ceramics are a unique class of structure materials with potential applications as high-temperature heat-resistant structural components owing to their combination of special structure and properties of low specific weight,high specific strength and excellent damage tolerance at elevated temperatures.However,it is still in need for further mechanical properties improvements for actual demands by rational co-design of architecture and chemistry as well as understanding the basic features of morphological/microstructural evolution and failure behavior.Thus in this attempt,to target the dense amorphous Si2ByC2N(y=1.5~4)monoliths with high mechanical properties,an attractive way of combinatorial mechanical alloying and high-pressure sintering technique(1 000℃/3~5 GPa/30 min)was proposed using elemental powders of graphite,hexagonal BN,cubic Si and boron as raw materials.The sintering pressure induced microstructural evolution,phase transformation and thermal stability have been investigated by XRD,SEM,TEM and TG measurements,and mechanical performance,especially the fracture behavior was also discussed in details.Results clearly presented that an increase in sintering pressure promoted the phase transformation of completely amorphous matrix to a hybrid structure of substantial amorphous phases and few nanocrystals of metal c-Si and/or t-BN(C)for some monoliths,implying boron-content depending phase composition.High-pressure sintering effectively promoted the densification leading to free volume annihilation and the river-like fracture morphology occurrence.A monotonous increase of the bulk density,nano hardness and Young’s modulus as a function of the sintering pressure was observed.Under the same sintering conditions,the increase in boron content weakened the mechanical properties and thermal stability of the amorphous Si2ByC2N(y=1.5~4)monoliths.Dense amorphous Si2B1.5C2N monoliths consolidated at 1 000℃/5 GPa/30 min showed the best performance with the bulk density,nano hardness and Young’s m

关 键 词：SiBCN 非晶陶瓷 显微结构 力学性能 硬度 

分 类 号：TQ174.75[化学工程—陶瓷工业]