Fabrication of onion-like carbon from nanodiamond by annealing 被引量：1

Fabrication of onion-like carbon from nanodiamond by annealing

导出

摘要 Onion-like carbon(OLC)was synthesized by annealing nanodiamond in low vacuum of 1 Pa and at annealing temperatures from 500℃to 1400℃.The high-resolution transmission electron microscope (HRTEM)images,X-ray diffraction(XRD)and Raman spectrum of the OLC showed that there was no OLC when the annealing temperature was lower than 900℃.Moreover,the fragment amorphous carbon existed on the surfaces of the nanodiamond particles.At the annealing temperature of 900℃,the OLC particles began appearing and the size of the OLC particles was smaller than 5 nm.When the annealing temperature was increased from 900℃to 1400℃,the nanodiamond was transformed into OLC gradu- ally.At the annealing temperature of 1400℃,all the nanodiamond particles were transformed into OLC completely.The OLC exhibited similarity to the original nanodiamond particles in shape.A mechanism for the OLC synthesis by annealing was provided.The graphitization started at the surfaces of the nanodiamond particles.The formation process of the OLC includes formation of graphite fragments, connection and curvature of graphite sheets between diamond(111)planes and closure of the graphite layers. Onion-like carbon (OLC) was synthesized by annealing nanodiamond in low vacuum of 1 Pa and at annealing temperatures from 500°C to 1400°C. The high-resolution transmission electron microscope (HRTEM) images, X-ray diffraction (XRD) and Raman spectrum of the OLC showed that there was no OLC when the annealing temperature was lower than 900°C. Moreover, the fragment amorphous carbon existed on the surfaces of the nanodiamond particles. At the annealing temperature of 900°C, the OLC particles began appearing and the size of the OLC particles was smaller than 5 nm. When the annealing temperature was increased from 900°C to 1400°C, the nanodiamond was transformed into OLC gradually. At the annealing temperature of 1400°C, all the nanodiamond particles were transformed into OLC completely. The OLC exhibited similarity to the original nanodiamond particles in shape. A mechanism for the OLC synthesis by annealing was provided. The graphitization started at the surfaces of the nanodiamond particles. The formation process of the OLC includes formation of graphite fragments, connection and curvature of graphite sheets between diamond (111) planes and closure of the graphite layers.

作者 Qin Zou MingZhi Wang YanGuo Li YuCheng Zhao LiangHua Zou

机构地区 State Key Laboratory of Metastable Materials Science and Technology

出处《Science China(Technological Sciences)》 SCIE EI CAS 2009年第12期3683-3689,共7页 中国科学（技术科学英文版）

关键词 onion-like carbon(OLC) NANODIAMOND ANNEALING FABRICATION onion-like carbon (OLC) nanodiamond annealing fabrication

分类号 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6

1杨修春,张孝彬,张泽,丁子上,周国治.一种制备巴基葱的新方法──纳米碳化硅高温真空热分解法[J].物理学报,1998,47(6):1052-1056. 被引量：2
2姜鹏,姚可夫.水中电弧法制备碳纳米葱[J].新型炭材料,2007,22(4):332-336. 被引量：3
3王柏春,朱永伟,陈立舫,许向阳,沈湘黔.爆轰产物法合成纳米金刚石研究现状[J].矿冶工程,2002,22(3):96-100. 被引量：7
4刘虹雯,侯士敏,刘赛锦,陶成钢,施祖进,顾镇南,彭练矛,吴锦雷,薛增泉.多层碳纳米球的研究[J].物理化学学报,2001,17(5):427-431. 被引量：2
5邹芹,王明智,王艳辉.纳米金刚石的性能与应用前景[J].金刚石与磨料磨具工程,2003,23(2):54-58. 被引量：31
6许向阳,朱永伟,王柏春,沈湘黔.水介质中纳米金刚石表面改性研究[J].中国粉体技术,2003,9(4):30-34. 被引量：4

二级参考文献48

1陈传盛,陈小华,刘天贵,杨东,张刚,易国军.碳纳米管的化学修饰以及作为润滑油添加剂的摩擦学性能研究[J].化学学报,2004,62(14):1367-1372. 被引量：17
2王晓敏.第八届亚太地区电镜显微学会会议简况[J].新型炭材料,2004,19(3):165-165. 被引量：2
3徐康,金增寿,魏发学,江天籁.炸药爆炸法制备超细金刚石粉末[J].含能材料,1993,1(3):19-21. 被引量：21
4阎逢元,张绪寿,薛群基,徐康.一种新型的减摩耐磨复合电镀层[J].材料研究学报,1994,8(6):573-576. 被引量：29
5王和照,张建军.金刚石薄膜的性质及其应用[J].新技术新工艺,1994(4):27-28. 被引量：1
6李天保,许并社,韩培德,张艳,王晓敏,刘旭光,市野濑英喜.洋葱状富勒烯的CCVD法制备及其形貌特征[J].新型炭材料,2005,20(1):23-27. 被引量：22
7张仿清,张文军,胡博,谢二庆,陈光华.硼掺杂及未掺杂金刚石薄膜的电学和光电导特性[J].Journal of Semiconductors,1995,16(10):783-788. 被引量：3
8周刚,恽寿榕,黄风雷.超细金刚石对应的碳液滴生成时间估算[J].爆炸与冲击,1995,15(4):350-355. 被引量：1
9李泉,曾广赋,席时权.纳米粒子[J].化学通报,1995(6):29-34. 被引量：143
10苏堤,陈本敬.热丝CVD金刚石薄膜Auger电子能谱分析[J].人工晶体学报,1995,24(1):54-58. 被引量：1

共引文献43

1李立明,邵建兵,朱永伟.Ni-P-金刚石化学复合镀研究工艺对镀层硬度的影响[J].金刚石与磨料磨具工程,2009,29(1):27-31. 被引量：1
2李春林,陈建.石墨类型对多晶金刚石微粉性能的影响[J].金刚石与磨料磨具工程,2012,32(4):51-54. 被引量：1
3马新起,郭新勇,金振声,杨建军,张治军.橄榄状纳米材料的制备与表征[J].现代化工,2004,24(9):44-45. 被引量：1
4王光祖.人造金刚石合成技术开拓创新的50年[J].金刚石与磨料磨具工程,2004,24(6):73-77. 被引量：25
5鲍学进,李成明,李浩,吕反修.含纳米金刚石粉镍钴基复合镀层的研究[J].金刚石与磨料磨具工程,2006,26(1):39-42. 被引量：2
6邓小清,贺红亮,唐敬友,方家元.纳米碳化硅的高温高压稳定性研究[J].长沙电力学院学报（自然科学版）,2006,21(2):80-83.
7孙景,江雷,杜希文,雷贻文,翟琪,杨星.激光轰击法制备纳米金刚石的提纯研究[J].炭素技术,2006,25(4):10-14.
8于雁武,刘玉存,刘登程,王建华.化学复合镀Ni-P-UFD的工艺研究[J].火工品,2007(1):15-17.
9张玉敏,刘桂华.金刚石超细粉体粒度测试中分散条件的探索[J].金刚石与磨料磨具工程,2007,27(2):17-19. 被引量：4
10靳洪允,侯书恩,杨晓光.纳米金刚石抛光液制备及应用[J].金刚石与磨料磨具工程,2007,27(3):67-71. 被引量：5

同被引文献20

1王艳辉,王明智,李宝余.高温超高压条件对Si中介结合的聚晶金刚石（PCD）组织与耐磨性的影响[J].复合材料学报,1994,11(2):57-61. 被引量：8
2洪时明,罗湘捷,陈叔鑫,姜仁柱,芶清泉.D—D结合型金刚石聚晶的高压合成研究[J].高压物理学报,1990,4(2):105-113. 被引量：7
3李明阳.碳化硅和硅结合的聚晶金刚石及其制造方法[J].超硬材料,1992(3):22-27.
4Wentorf R H, De Vries R C, Bundy F P. Sintered superhard materi- als[J ]. Science, 1980,208:873.
5Jia H S, Ma H G, Jia X P. Research on polycrystalline diamond com- pact(PDC) with low residual stress prepared using nickel-based addi- tive[ J ]. International Journal of Refractory Metals & Hard Materials, 2011,29:64-67.
6Krawitz A D, Winholtz R A, Drake E F. Residual stresses in poly- crystalline diamond compacts [ J ]. International Journal of Refractory Metals & Hard Materials, 1999,17 : 117-122.
7Lin T P, Hood M, Cooped G A. Residual stresses in polycrystalline diamond compacts [ J ]. Journal of the American Ceramic Society, 1994,77:1562-1568.
8Lin T P, Hood M, Cooper G A. Wear and failure mechanisms of pely- crystalline diamond compact bits [ J ]. Wear, 1992,156 : 133-1506.
9Miess D, Rai G. Fracture toughness and thermal resistance of poly- crystalline diamond compacts [ J ]. Material Science & Engineering A, 1996,209:270-276.
10Nabhani H. Wear mechanisms of ultra-hard cutting tools materials [ J ]. Journal of Materials Processing Technology, 2001,115:402-412.

引证文献1

1邹芹,王明智,余强化,李艳国,柯雨蛟,唐虎,赵玉成,尹育航.微米金刚石含量对圆葱碳烧结制备聚晶金刚石(PCD)组织及性能的影响[J].矿冶工程,2015,35(6):140-144. 被引量：1

二级引证文献1

1梁宝岩,王长通,罗毅潼,韩丹辉.纳米金刚石核/洋葱状碳壳材料的可见光光催化活性研究[J].中原工学院学报,2023,34(6):11-16.

1邹芹.Fabrication of Onion-like Carbon Using Nanodiamond by Annealing at Lower Temperature and Vacuum[J].Journal of Wuhan University of Technology(Materials Science),2009,24(6):935-939.
2Yongwei ZHU,Feng XU,Jianliang SHEN,Baichun WANG,Xiangyang XU,Jianbin SHAO.Study on the Modification of Nanodiamond with DN-IO[J].Journal of Materials Science & Technology,2007,23(5):599-603.
3Huan Huan Zhang Ya Ting Liu Rong Wang Xiao Yan Yu Xiong Wei Qu Qing Xin Zhang.Functionalization of nanodiamond with epoxy monomer[J].Chinese Chemical Letters,2011,22(4):485-488.
4Yongwei ZHU,Yongjun CHEN,Changhong ZHU,Xiangqian SHEN.Ni-P-Nanodiamond composite electroless plating[J].Acta Metallurgica Sinica(English Letters),2010,23(6):409-415. 被引量：4
5Xiao-wei MA Yu-liang ZHAO Xing-jie LIANG.Nanodiamond delivery circumvents tumor resistance to doxorubicin[J].Acta Pharmacologica Sinica,2011,32(5):543-544. 被引量：1
6Sobia A.Rakha,Naveed Ali,Yasir A.Haleem,Fakhre Alam,Aqeel A.Khurram,Arshad Munir.Comparison of Mechanical Properties of Acid and UV Ozone Treated Nanodiamond Epoxy Nanocomposites[J].Journal of Materials Science & Technology,2014,30(8):753-758.
7YongweiZhu,XiangyangXu,BaichunWang,ZhijingFeng.SURFACE MODIFICATION AND DISPERSION OF NANODIAMOND IN CLEAN OIL[J].China Particuology,2004,2(3):132-134. 被引量：4
8Wei Jia,Yuen Wu,Yifeng Chen,Dongsheng He,Jinpeng Li,Yu Wang,Zhuo Wang,Wei Zhu,Chen Chen,Qing Peng,Dingsheng Wang,Yadong Li.Interface-induced formation of onion-like alloy nanocrystals by defects engineering[J].Nano Research,2016,9(2):584-592. 被引量：5
9Jing Wei ZHANG,Xin Yong GUO,Zhen Sheng JIN,Shun Li ZHANG,Jing Fang ZHOU,Zhi Jun ZHANG.TEM Study on the Formation Process of TiO_2 Nanotubes[J].Chinese Chemical Letters,2003,14(4):419-422. 被引量：7
10楚亚卿,仝毅,张同来,黄风雷.Mechanical properties of dental composite resins containing nanodiamond of different diameters[J].Journal of Beijing Institute of Technology,2012,21(1):19-22. 被引量：1

Science China(Technological Sciences)

2009年第12期

浏览历史

内容加载中请稍等...