欢迎登录材料期刊网

材料期刊网

高级检索

以氟硼酸盐和氨基钠为反应原料,氨基钠或金属钠为生长介质,在600℃下恒温反应24h,成功制备出了三角形和六边形片状氮化硼微晶。XRD、FT-IR和XPS分析表明,产物为六方氮化硼,无其它物相存在。FESEM和TEM分析发现在氨基钠熔体中产物为三角形片晶,而在氨基钠和钠混合熔体中得到的是六边形的氮化硼片晶。三角形片晶边长约400~500nm,厚度约为100nm;六边形片晶的边长在300~500nm范围内,厚度约100~150nm。研究结果表明,NaNH2不仅能作为氮源,同时也是氮化硼晶体生长的介质。

Triangles and hexagons BN were prepared by using NaBF4 and Na as raw material, NaNH2 or Na as the growth medium at 600℃ for 24 h. The identification of BN was studied by using XRD, FT-IR and XPS. The morphology of phases were characterized with FESEM and TEM. The results showed that triangles BN and hexagons BN can be obtained in the growth medium of NaNH2 and in the presence of NaNH2 and Na re- spectively. The triangles BN has a length about 400-500nm and 100nm in height while the hexagons BN has a length at 300-500nm and 100-150nm in height. The results indicated that NaNH2 not only act as the nitrogen source but also can be used as the growth medium of BN.

参考文献

[1] A. Aydogdu;N. Sevinc .Carbothermic formation of boron nitride[J].Journal of the European Ceramic Society,2003(16):3153-3161.
[2] Eugene A.Pruss;Gary L.Wood;William J.Kroenke;Robert T.Paine .Aerosol Assisted Vapor Synth4esis of Spherical Boron Nitride Powders[J].Chemistry of Materials,2000(1):19-21.
[3] Borovinskaya I P;Ignat'eva T I;Vershinnikov V I et al.Preparation of ultrarine boron nitride powders by self- propagating high-temperature synthesis[J].Inog Mater,2003,39(06):588-593.
[4] Baraton M I;Boulanger L;Cauchetier M;et ah .Nano- metric boron nitride powders:laser synthesis,character- ization and FT-IR surface study[J].Journal of the European Ceramic Society,1994,13(04):371-378.
[5] D. Cornu;S. Bernard;S. Duperrier .Alkylaminoborazine-based precursors for the preparation of boron nitride fibers by the polymer-derived ceramics (PDCs) route[J].Journal of the European Ceramic Society,2005(2/3):111-121.
[6] Yu M Y;Cui D L;Kai L et al.Hydrothermal synthesis of cubic boron nitride crystals[J].Materials Science and Engineering B,2005,121(1-2):166-169.
[7] 董守义,郝霄鹏,于美燕,李凯,王琪珑,蒋民华,崔得良.GaP纳米晶对溶剂热合成氮化硼的物相和微观形貌的影响[J].功能材料,2004(06):695-697.
[8] Xu F.;Xie Y.;Zhang X.;Zhang SY.;Liu XM.;Tian XB. .Synergic nitrogen source route to inorganic fullerene-like boron nitride with vessel, hollow sphere, onion, and peanut nanostructures[J].Inorganic Chemistry: A Research Journal that Includes Bioinorganic, Catalytic, Organometallic, Solid-State, and Synthetic Chemistry and Reaction Dynamics,2004(2):822-829.
[9] Xu LQ.;Peng YY.;Meng ZY.;Yu WC.;Zhang SY.;Liu XM.;Qian YT. .A co-pyrolysis method to boron nitride nanotubes at relative low temperature[J].Chemistry of Materials,2003(13):2675-2680.
[10] Narita I;Oku T;Tokoro H;Suganuma K .Synthesis of Co nanocapsules coated with BN layers by annealing of KBH4 and [Co(NH3)(6)]Cl-3[J].Solid State Communications,2006(1/2):44-48.
[11] Nishiwaki A;Oku T .Atomic structures and {ormation mechanism of boron nitride nanotubes and nanohorns synthesized by arc-melting LaB6 powders[J].Journal of the European Ceramic Society,2006,26(4-5):435-441.
[12] Shi L.;Gu YL.;Chen LY.;Qian YT.;Yang ZH.;Ma JH. .Synthesis and morphology control of nanocrystalline boron nitride[J].International Journal of Quantum Chemistry,2004(3):721-724.
[13] Changgu Lee;Qunyang Li;William Kalb;Xin-Zhou Liu;Helmuth Berger;Robert W. Carpick;James Hone .Frictional Characteristics of Atomically Thin Sheets[J].Science,2010(Apr.2 TN.5974):76-80.
[14] Zhi C;Bando Y;Tang C et al.Large scale fabrication of boron nitride nanosheets and their utilization in poly- meric composites with improved thermal and mechanical properties[J].Advanced Materials,2009,21:2889-2893.
[15] 陈贵清,韩杰才,张宇民,张卫方,杜善义.高压气-固自蔓延高温合成h-BN-SiO2陶瓷材料的研究[J].无机材料学报,1999(03):437-442.
[16] Caicedo JM;Bejarano G;Zambrano G;Baca E;Moran O;Prieto P .Cubic and hexagonal boron-nitride (c-BN/h-BN) thin films deposited in situ by r.f. magnetron sputtering[J].Physica status solidi, B. Basic research,2005(9):1920-1923.
[17] 李梦华 .氮化硼物相与形貌控制的合成研究[D].山东大学,2010.
上一张 下一张
上一张 下一张
计量
  • 下载量()
  • 访问量()
文章评分
  • 您的评分:
  • 1
    0%
  • 2
    0%
  • 3
    0%
  • 4
    0%
  • 5
    0%