Preparation of Nano-sized Zirconium Carbide Powders through a Novel Active Dilution Self-propagating High Temperature Synthesis Method 被引量：6

Preparation of Nano-sized Zirconium Carbide Powders through a Novel Active Dilution Self-propagating High Temperature Synthesis Method

下载PDF

导出

摘要 High quality nano-sized zirconium carbide （ZrC） powders were successfully fabricated via a developed chemical active dilution self-propagating high-temperature synthesis （SHS） method assisted by ball milling pretreatment process using traditional cheap zirconium dioxide powder （ZrO2）, magnesium powder （Mg） and sucrose （C12H22Oll） as raw materials. FSEM, TEM, HRTEM, SAED, XRD, FTIR and Raman, ICP- AES, laser particle size analyzer, oxygen and nitrogen analyzer, carbon/sulfur determinator and TG-DSC were employed for the characterization of the morphology, structure, chemical composition and thermal stability of the as-synthesized ZrC samples. The as-synthesized samples demonstrated high purity, low oxygen content and evenly distributed ZrC nano-powders with an average particle size of 50nm. In addition, the effects of endothermic rate and the possible chemical reaction mechanism were also discussed. High quality nano-sized zirconium carbide （ZrC） powders were successfully fabricated via a developed chemical active dilution self-propagating high-temperature synthesis （SHS） method assisted by ball milling pretreatment process using traditional cheap zirconium dioxide powder （ZrO2）, magnesium powder （Mg） and sucrose （C12H22Oll） as raw materials. FSEM, TEM, HRTEM, SAED, XRD, FTIR and Raman, ICP- AES, laser particle size analyzer, oxygen and nitrogen analyzer, carbon/sulfur determinator and TG-DSC were employed for the characterization of the morphology, structure, chemical composition and thermal stability of the as-synthesized ZrC samples. The as-synthesized samples demonstrated high purity, low oxygen content and evenly distributed ZrC nano-powders with an average particle size of 50nm. In addition, the effects of endothermic rate and the possible chemical reaction mechanism were also discussed.

作者达奥运龙飞 WANG Jilin XING Weihong WANG Yang ZHANG Fan 王为民 FU Zhengyi

机构地区 State Key Laboratory of Advanced Technology for Materials Synthesis and Processing Key Lab of New Processing Technology for Nonferrous Metals & Materials Ministry of Education

出处《Journal of Wuhan University of Technology(Materials Science)》 SCIE EI CAS 2015年第4期729-734,共6页 武汉理工大学学报（材料科学英文版）

基金 Funded by the Program for New Century Excellent Talents in University(No.NCET-12-0655) the Guangxi Natural Science Foundation(No.2014GXNSFFA118004) the Self-determined and Innovative Research Funds of WUT(Nos.136643002 and No.2013IV058)

关键词 zirconium carbide ZRC self-propagating high-temperature synthesis active dilution NANO-POWDERS ball milling zirconium carbide ZrC self-propagating high-temperature synthesis active dilution nano-powders ball milling

分类号 TQ134.12 [化学工程—无机化工] TB383.1 [一般工业技术—材料科学与工程]

引文网络
相关文献

参考文献2

1李静,傅正义,王为民,王皓,李秀完,新原浩一.自蔓延高温技术制备ZrC粉体(英文)[J].硅酸盐学报,2010,38(5):979-985. 被引量：14
2翟林峰,史铁钧,王华林.低pH值条件下纤维状ZrO_2水合物的制备及其形成机理研究[J].无机材料学报,2007,22(2):223-226. 被引量：7

二级参考文献37

1CUI Xuemei, YOUNG S N, LEE J Y, et al. Fabrication of zirconium carbide (ZrC) ultra-thin fibers by electrospinning [J]. Mater Lett, 2008,62: 1961-1964.
2SONG M S, HUANG B, ZHANG M X, et al. Formation and growth mechanism of ZrC hexagonal platelets synthesized by self-propagating reaction [J]. J Cryst Growth, 2008, 310: 4290-4294.
3VASUDEVAMURTHY G, KNIGHT T W. Laboratory production of zirconium carbide compacts for use in inert matrix fuels [J]. J Nucl Mater, 2008, 374: 241-247.
4MAITRE A, LEFORT P. Solid state reaction of zirconia with carbon [J]. Solid State Ionics, 1997, 104: 109-122.
5YAN Y J. Carbothermal synthesis of ultra-fine zirconium carbide powders using inorganic precursors via sol-gel method [J]. J Sol-Gel Sci Technol, 2007, 44:81-85.
6KOBAYASHI H. Low-temperature synthesis of ZrC powder by cyclic reaction of Mg in ZrO2-Mg-CH4 [J]. JArn Ceram Soc, 1993, 76: 89- 92.
7MAHDAY A A. Mechanically induced solid state carburization for fabrication of Nano-crystalline ZrC refractory material powders [J]. J Alloys Compd, 2000, 299: 244-253.
8LI Jing, FU Zhengyi, ZHANG Jinyong, et al. Preparation of ZrC powder by self-propagating high-temperature synthesis [J]. Adv Mater Res, 2009, 66: 258-261.
9FU Zhengyi, WANG Weimin, WANG Hao, et al. Fabrication of cermets by SHS/QP method [J]. Int J SHS, 1993, 2(3): 307-310.
10YUAN Ruizhang, FU Zhengyi, WANG Weimin, et al. SHS TiB2-based multiphase ceramics and composites [J]. Int J SHS, 2001, 10(4): 435- 440.

共引文献19

1翟林峰,史铁钧,王华林,于少明.ZrO_2/聚乙烯醇杂化电纺纤维的制备和性能[J].材料研究学报,2008,22(2):182-186. 被引量：2
2翟林峰,史铁钧,于少明.可纺性锆溶胶的制备与应用Ⅰ.氧化锆连续纤维的制备[J].应用化学,2008,25(6):637-641. 被引量：11
3梅冰,苏勋家,侯根良,王延斌.液相先驱体转化法制备ZrC粉末及合成机理[J].固体火箭技术,2008,31(3):275-278. 被引量：17
4杨玮娇,唐清,李锐星,柳海涛,李会泉.H_2O_2改性溶胶-凝胶法制备ZrO_2基催化剂载体[J].过程工程学报,2009,9(4):819-823. 被引量：2
5黄岩,梁杰,陈瑞飞.外场技术在氧化锌矿浸出工艺中的应用[J].贵州大学学报（自然科学版）,2011,28(2):40-42. 被引量：3
6宋谋胜,冉茂武.自蔓延反应制备ZrC粉末的形成机制研究[J].粉末冶金技术,2011,29(3):177-182. 被引量：5
7赵彦伟,刘宏瑞,李军平,胡继东,陈海坤.ZrC粉体制备的研究进展[J].宇航材料工艺,2012,42(2):15-18. 被引量：3
8白柳杨,张海宝,袁方利,黄淑兰,李晋林.高频热等离子体合成超细ZrB_2和ZrC粉体材料[J].宇航材料工艺,2012,42(2):88-90. 被引量：6
9葛禹锡,黄锋,倪红军,朱昱.自蔓延高温合成法制备粉体的研究进展[J].热加工工艺,2012,41(12):75-78. 被引量：13
10黄庆,董志军,张贤,刘树仙,李轩科.液相先驱体法制备纳米ZrC陶瓷粉体[J].中国陶瓷,2013,49(5):17-21. 被引量：4

同被引文献50

1李庆刚,程新,王志,史国普.液相前驱体转化法制备ZrC及其表征[J].济南大学学报（自然科学版）,2013,27(3):221-224. 被引量：3
2方舟,王皓,傅正义.Zr-B_2O_3-Mg体系自蔓延高温合成ZrB_2陶瓷粉末[J].硅酸盐学报,2004,32(6):755-758. 被引量：19
3章晓波,刘宁.碳化硼材料的性能、制备与应用[J].硬质合金,2006,23(2):120-125. 被引量：34
4傅博,李盛荣,王永兰.碳化硼陶瓷材料密度的控制方法与应用[J].辽宁工学院学报,1997,17(2):44-47. 被引量：6
5梅冰,苏勋家,侯根良,王延斌.液相先驱体转化法制备ZrC粉末及合成机理[J].固体火箭技术,2008,31(3):275-278. 被引量：17
6闫永杰,张辉,黄政仁,刘学建,董绍明.无机盐溶胶-凝胶法制备超细ZrB2-ZrC复合粉体[J].无机材料学报,2008,23(4):815-818. 被引量：11
7宋瑞颖,刘宁,张红芹,刘忠伟,蔡威.ZrC陶瓷的性能、制备及应用[J].硬质合金,2009,26(2):134-140. 被引量：13
8周晓波,苏勋家,侯根良,王延斌,毕松.液相先驱体制备ZrC粉末研究[J].材料导报（纳米与新材料专辑）,2009,23(2):142-144. 被引量：2
9杜会静,郝锐.傅里叶变换红外光谱法检测硼碳氮亚稳态材料的进展[J].理化检验（化学分册）,2009,45(12):1460-1464. 被引量：3
10邹洪伟,叶金文,刘颖,夏珊,李平平.原料粉末碳、氧含量对无粘结相硬质合金性能的影响[J].功能材料,2010,41(1):90-93. 被引量：9

引证文献6

1李月星,范明聪,王吉林,陈亚兵,谷云乐.反应稀释自蔓延法制备碳化硼超细粉[J].武汉工程大学学报,2018,40(2):186-189. 被引量：2
2范明聪,吉钰纯,王吉林,谷云乐.间歇式推舟-CVD法制备竹节状氮化硼纳米管[J].武汉工程大学学报,2019,41(4):350-353. 被引量：1
3许珂,占发琦,张华,安宁,吴浩恺,朱敏,郑月红,喇培清.混合盐辅助燃烧合成纳米ZrC粉体及影响机制[J].功能材料,2021,52(10):10177-10186. 被引量：2
4占发琦,许世鹏,张华,刘枭,朱敏,郑月红,喇培清.ZrO_(2)粒径对盐助燃烧合成纳米ZrC微观结构的影响[J].硅酸盐通报,2023,42(12):4532-4541.
5任金翠,李欣沂,吴义胜.ZrB_(2)与ZrC单相粉末及ZrB_(2)-ZrC复合粉末制备现状[J].复合材料学报,2024,41(3):1124-1140.
6ZHANG Wangxi,LIANG Baoyan,LUO Wei,WANG Yanzhi.Hybrid Ti_2AlC Bonded Diamond Composites Prepared by a Self-propagation Sintering Approach[J].Journal of Wuhan University of Technology(Materials Science),2019,34(1):82-85. 被引量：4

二级引证文献9

1范明聪,吉钰纯,王吉林,谷云乐.间歇式推舟-CVD法制备竹节状氮化硼纳米管[J].武汉工程大学学报,2019,41(4):350-353. 被引量：1
2南钰,陈厚振,郑罡,宋瑞卿,冯明,秦泽华.六方氮化硼/聚合物导热复合材料的研究进展[J].中原工学院学报,2021,32(2):17-24. 被引量：1
3史冬丽,马尧,李涛,梁宝岩.以Mo/Al/B_(2)O_(3)/金刚石粉体热爆反应体系在金刚石颗粒表面形成镀覆涂层[J].工业技术创新,2022,9(5):47-52.
4张琦,梁宝岩,王长通,朱丹丹.金刚石表面热爆合成MnB-AlN基多元复合涂层的实验[J].中原工学院学报,2022,33(5):6-10.
5韩警贤,刘嘉霖.Cr/Al/B/diamond体系中金刚石表面的热爆反应涂层[J].金刚石与磨料磨具工程,2022,42(6):692-698. 被引量：1
6武美玲,尹育航,丁冬海,肖国庆,段锋,彭凯,杨潘,张立,敬臣.自蔓延高温合成法制备金刚石工具材料研究现状[J].材料热处理学报,2023,44(5):1-15.
7国运之.自蔓延高温合成法在陶瓷粉体制备中的应用[J].中国粉体工业,2023(4):26-27.
8占发琦,许世鹏,张华,刘枭,朱敏,郑月红,喇培清.ZrO_(2)粒径对盐助燃烧合成纳米ZrC微观结构的影响[J].硅酸盐通报,2023,42(12):4532-4541.
9任金翠,李欣沂,吴义胜.ZrB_(2)与ZrC单相粉末及ZrB_(2)-ZrC复合粉末制备现状[J].复合材料学报,2024,41(3):1124-1140.

1XUE Ru-jun,WU Yu-cheng.Mechanism and Microstructure of Electroless Ni-Fe-P Plating on CNTs[J].Journal of China University of Mining and Technology,2007,17(3):424-427. 被引量：7
2杨鑫,苏哲安,黄启忠,柴立元,钟平,薛亮.A zirconium carbide coating on graphite prepared by reactive melt infiltration[J].Journal of Central South University,2014,21(2):472-476. 被引量：2
3朱教群,李儒光,ZHOU Weibin,ZHANG Hongguang,CHENG Xiaomin.Fabrication of Al_2O_3-NaCl Composite Heat Storage Materials by One-step Synthesis Method[J].Journal of Wuhan University of Technology(Materials Science),2016,31(5):950-954. 被引量：5
4倪寿亮,白柳杨,袁方利.氧在ZrC中存在形态的研究[J].分析仪器,2016(4):94-98.
5Na Wei,Hong-Zhi Cui,Jie Wu,Jun Wang,Guan-Long Wang,Chen Jiang.Effects of Forming Conditions and TiC–TiB_2 Contents on the Microstructures of Self-Propagating High-Temperature Synthesized NiAl–TiC–TiB_2 Composites[J].Acta Metallurgica Sinica(English Letters),2015,28(1):39-47. 被引量：4
6LI Lin,HONG Yan ruo,SUN Jia-lin,HE Zhi-yong,PENG Xiao-yan.Formation of ZrB2in MgO-C Composite Materials Using In-Situ Synthesis Method[J].Journal of Iron and Steel Research International,2006,13(1):70-74. 被引量：3
7Xue Yu Tao,Wen Feng Qiu,Hao Li,Tong Zhao,Xian Yong Wei.New route to synthesize preceramic polymers for zirconium carbide[J].Chinese Chemical Letters,2012,23(9):1075-1078. 被引量：3
8李中军,黄银霞,要红昌,杨民乐,陈建立.碳化锆碱熔制备氧氯化锆的研究[J].稀有金属,2006,30(3):415-418. 被引量：7
9谢卓明,刘瑞,方前锋,张涛,蒋燕,王先平,刘长松.Microstructure and Mechanical Properties of Nano-Size Zirconium Carbide Dispersion Strengthened Tungsten Alloys Fabricated by Spark Plasma Sintering Method[J].Plasma Science and Technology,2015,17(12):1066-1071. 被引量：9
10谢华林,李坦平.微波消解ICP-AES法测定水泥中硫的研究[J].水泥技术,2004(3):94-95. 被引量：4

Journal of Wuhan University of Technology(Materials Science)

2015年第4期

浏览历史

内容加载中请稍等...