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激光诱导合成金刚石的机理研究 被引量:5

Mechanism of synthesizing diamond by laser introduction
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摘要 本文对激光诱导合成金刚石的机理进行了多方面的较深入的探索。首次估算了石墨直接转化金刚石所必须越过的势垒值为8.565×104J.mol-1。说明了宏观高压并非是这一转化的必要条件。对于激光诱导合成金刚石,其激光源的功率密度不应低于2.534×105W.cm-2。提出并计算了有利于激光诱导合成金刚石的若干因素:靶前激光维持爆轰波的压力可达几个GPa数量级;粒径为4nm的石墨微粒,其晶体本身表面高压可达3.32GPa;石墨被加热后,其晶体自身的热压力可达几百MPa;晶体表面原子振幅远大于体内,其动能可达1.6×10-19J;被激光照射时,石墨原子的平均振幅大到常温时的8倍以上。用细微石墨颗粒作原料更易于合成金刚石。将宏观的热力学理论与微观的物质结构及相变的微观机理结合起来,能较好地阐明该相变机理。 In this paper, the mechanism of synthesizing diamond by laser introduction was explored in many ways. It was evaluated for the fimt time that the minimum potential energy for transforming graphite into diamond is 8.565×10^4J mol^-1. Macroscopic high pressure is not necessary condition for the transforming. For introducing graphite to diamond, The laser beam power density should not be lower than 2.534×10^5W·cm^-2. Some beneficial factors to synthesize diamond by laser introduction have been pointed and calculated. The peak pressure on the surface of target can be up to several GPa grade; For a size of 4nm graphite micrograin, its surface high pressure can reach 3.32GPa; Its heat pressure can be up to hundreds of MPa while the graphite is heated; Atom amplitude on the crystal surface is much larger than inside body, its kinetic energy can be up to 1.6×10^-19J; The mean amplitude of graphite atom while irradiated is 8 times larger than in normal temperature; It is more easily for synthesizing diamond by using finer micrograin of graphite. The mechanics on the phase transfer could be explained clearer and deeper by combining material micro structure, micro mechanics of phase transform and macro thermodynamic theory.
出处 《金刚石与磨料磨具工程》 CAS 北大核心 2005年第6期1-5,共5页 Diamond & Abrasives Engineering
基金 国家自然科学基金项目资助(编号:50372043) 天津市科技培育项目资助(编号:043101211)
关键词 机理 金刚石 合成 激光 相变 石墨 势垒计算 mechanism diamond synthesize laser phase-transforming graphite potential energy calculation
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参考文献23

  • 1将翔六.金刚石薄膜研究进展[M].北京:化学工业出版社,1991.
  • 2王有起,张书达.金刚石薄膜CVD制备技术及其应用[A].天津青年学术精粹,天津:天津大学出版社,1995:771-774.
  • 3Fedoseev D V,Bukhovets V L,Varshvskaya I G,et al.Transition of graphite into diamond in a solid phase under the atmospheric pressure[J].Carbon,1983,21,237-241.
  • 4Ogale S B,Malshe A P,Kanetkar S M,et al.Formation of diamond particulates by pulsed ruby-laser irradiation of graphite immersed in.benzene[J].Solid State Communications,1992,84,371-373.
  • 5Alam M,Debroy T,Roy R,et al.Diamond Formation in Air by the Fedoseev-Dergaguin Laser Process[J].Carbon,1989,27:289-294.
  • 6王金斌,刘秋香,杨国伟,胡国彬,游建强.脉冲激光诱导液-固界面反应制备金刚石纳米晶[J].材料研究学报,1998,12(3):323-325. 被引量:7
  • 7Yang Guowei,Wang Jinbin,Pulsed-laser-induced transformation path of graphite to diamond via an intermediate rhombohedral graphite[J].Applied Physics A:Materials Science & Processing,2001,724(4):475-479.
  • 8孙景,杨星,雷贻文,翟琪,杨晶,杜希文.激光诱导固态转变合成金刚石研究进展[J].金刚石与磨料磨具工程,2005,25(2):7-9. 被引量:6
  • 9Bundy F P.Direct Conversion of Graphite to Diamond in Static Pressure Apparayus[J].Journal of Chemical Physics,1963,38(3):631-643.
  • 10Berman R,Simon F,The graphite diamond equilibrium[J].Zeit fur Electrochemie,1955,59:333-338.

二级参考文献28

  • 1Xiong F L,J Mater Res,1993年,8卷,2265页
  • 2吴元康,人工晶体学报,1991年,20卷,127页
  • 3王育煌,高等学校化学学报,1997年,18卷,124页
  • 4Xiao R F,Appl Phys Lett,1995年,67卷,305页
  • 5Yusa H. Diam Rel Mater, 2002, 11 : 87.
  • 6Bundy F P, Hall H T, Strong H M, et al. Nature, 1955,176:51 ~55.
  • 7DeCarli P S, Jamieson J C. Science, 1961, 133 : 1821 ~1822.
  • 8Derjaguin B V , Fedoseev D V. Scientific American, 1975,233(5) : 102 ~ 109.
  • 9Rebello J H D, Subramaniam V V, Sudarshan T S. Appl Phys Lett, 1993, 62: 899.
  • 10Molian P A, Waschek A J. Mater Sci, 1993, 28: 1733.

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