叠氮唑类高氮含能化合物的理论研究

化学学报 ›› 2011, Vol. 69 ›› Issue (06): 610-616. 上一篇下一篇

研究论文

叠氮唑类高氮含能化合物的理论研究

牛晓庆¹，张建国^*,1，王颖¹，陈陶平²，张绍文³，张同来¹，周遵宁¹，杨利¹

(¹北京理工大学爆炸科学与技术国家重点实验室北京 100081)
(²邯郸学院图书馆邯郸 056002)
(³北京理工大学理学院北京 100081)

投稿日期:2010-08-28 修回日期:2010-11-01 发布日期:2010-11-18
通讯作者: 张建国 E-mail:zhangjianguobit@yahoo.com.cn
基金资助:
国家自然科学基金项目; 国家自然科学基金委-中国工程物理研究院联合基金; 教育部新世纪优秀人才支持计划

Theoretical Studies of Azide-Azole Nitrogen-Rich Energetic Compounds

Niu Xiaoqing¹ , Zhang Jianguo^*,1 Wang Ying¹ Chen Taoping² Zhang Shaowen³ Zhang Tonglai¹ Zhou Zunning¹ Yang Li¹

(¹State Key Laboratory of Explosion Science and Technology, Beijing Institute of Technology, Beijing 100081)
(² Library of Handan College, Handan 056002)
(³School of Science, Beijing Institute of Technology, Beijing 100081)

Received:2010-08-28 Revised:2010-11-01 Published:2010-11-18
Contact: Jianguo Zhang E-mail:zhangjianguobit@yahoo.com.cn

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摘要/Abstract

基于2-叠氮-1,3-咪唑、3-叠氮-1,2,4-三唑和5-叠氮-1氢-四唑的晶体结构数据, 自行设计了同系列化合物叠氮-五唑的分子结构. 采用B3LYP方法, 选取6-311＋＋G**基组, 对叠氮唑类化合物进行优化并得到了稳定的分子构型, 结构参数与现有的实验数据相符. 故在此水平下对此系列化合物进行红外振动、键级及自然键轨道分析, 计算结果表明, 所有化合物均无虚频, 为势能面上的稳定结构, 分子中存在一个大的共轭体系|根据前线轨道能隙差(ΔE_L-H)得到4种化合物的热稳定顺序为: 5-叠氮-1-氢-四唑＞3-叠氮-1,2,4-三唑＞叠氮-五唑＞2-叠氮-1,3-咪唑|计算得到的生成热、密度、爆速爆压均随着体系中含氮量的增加而增加, 即叠氮-五唑的爆速、爆压最大, 爆速达到了9897 m•s^－1, 爆压达到了46.0 GPa, 在含能材料领域具有潜在的应用前景.

关键词: 高氮化合物, 结构优化, 振动分析, 生成热, 爆速, 爆压

Based on the crystal data of 2-azido-1,3-imidazole, 3-azido-1,2,4-triazole and 5-azido-1H-tetrazole, a novel of azido-pentazole was firstly devised. The most stable molecular geometries of azide-azole compounds were obtained using B3LYP methods with 6-311＋＋G** basis set. Compared with existing experimental data, B3LYP/6-311＋＋G** is the suitable basis set for compounds. Moreover, IR spectra and bond order of azide-azole nitrogen-rich energetic compounds were obtained. The results show that they have not imaginary frequencies, so they were stable on the potential energy surface. There is a great conjugate system among molecular structures. The frontier orbital energies and their differences predict that the stabilities of the title compounds decrease in the order: 5-azido-1H-tetrazole＞3-azide-1,2,4-triazole＞azido-pentazole＞2-azido-1,3-imidazole. The results show that heat of formation, density, detonation velocity and detonation pressure of the title compounds linearly increase with increasing nitrogen mass fraction in the system. Azido-pentazole with detonation velocity of 9897 m•s^－1, and the detonation pressure of 46.0 GPa, which has potential applications in the high energy density materials.

Key words: nitrogen-rich compounds, molecular geometry, frequency analysis, heat of formation, detonation velocity, detonation pressure

引用此文

牛晓庆, 张建国, 王颖, 陈陶平, 张绍文, 张同来, 周遵宁, 杨利. 叠氮唑类高氮含能化合物的理论研究[J]. 化学学报, 2011, 69(06): 610-616.

NIU Xiao-Qing, ZHANG Jian-Guo, WANG Ying, CHEN Tao-Ping, ZHANG Shao-Wen, ZHANG Tong-Lai, ZHOU Zun-Ning, YANG Li. Theoretical Studies of Azide-Azole Nitrogen-Rich Energetic Compounds[J]. Acta Chimica Sinica, 2011, 69(06): 610-616.

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参考文献

1 Zhou,S.G.; Wu,W.J.Chin.Ind.Times 1997,11,3 (in Chinese).

(周世光,吴文健,化工时刊,1997,11,3.)

2 Kerth,J.; Löbbecke,S.Propellants,Exoplos.,Pyrotech.2002,27,111.

3 Hiskey,M.; Chavez,D.E.Progress in High-nitrogen Chemistry in Explosives,Propellants and Pyrotechnics,27th International Pyrotechnics Seminar,Colorado,USA,2000,pp.3～14.

4 Sun,Z.; Zeng,X.-Q.; Wang,W.-G.; Ge,M.-F.Acta Chim.Sinica 2006,64,218 (in Chinese).

(孙政,曾小庆,王炜罡,葛茂发,化学学报,2006,64,218.)

5 Li,S.-H.; Shi,H.-G.; Sun,C.-H.; Li,X.-T.; Pang,S.-P.; Yu,Y.-Z.; Zhao,X.-Q.Chin.J.Energ.Mater.2009,17,7 (in Chinese).

(李生华,施宏刚,孙成辉,李小童,庞思平,于永忠,赵信歧,含能材料,2009,17,7.)

6 Hammerl,A.; Klapötke,T.M.; Rocha,R.Eur.J.Inorg.Chem.2006,16,2210.

7 Swain,P.K.; Singh,H.; Tewari,S.P.J.Mol.Liq.2010,151,87.

8 Zhang,J.-G.; Zheng,H.-H.; Zhang,T.-L.; Feng,L.-N.Inorg.Chim.Acta 2008,361,4143.

9 Vilarrasa,J.; Melendez,E.An.Quim.1974,7,966.

10 Vilarrasa,J.; Olivella,S.J.Heterocycl.Chem.1979,16,685.

11 Habereder,T.; Hammerl,A.; Holl,G.; Klapötke,T.M.;Knizek,J.; Mayer,P.Inorg.Chem.2002,41,906.

12 Hammerl,A.; Klapötke,T.M.; Nolth,H.; Warchhold,M.;Holl,G.; Kaiser,M.Inorg.Chem.2001,40,3570.

13 Hammerl,A.; Klapötke,T.M.; Mayer,P.Propellants,Exoplos.,Pyrotech.2005,30,17.

14 Xue,H.; Gao,Y.; Twamley,B.J.Mater.Chem.2005,17,191.

15 Kofman,T.P.; Krasnov,K.N.Russ.J.Org.Chem.2004,40,1652.

16 Li,S.-H.; Pang,S.-P.; Li,X.-T.; Yu,Y.-Z.; Zhao,X.-Q.Chin.J.Org.Chem.2008,28,727 (in Chinese).

(李生华,庞思平,李小童,于永忠,赵信歧,有机化学,2008,28,727.)

17 Hammerl,A.; Klapötke,T.M.Inorg.Chem.2004,41,906.

18 Denffer,M.; Klapötke,T.M.; Kramer,G.; Welch,J.M.;Heeb,G.Propellants,Exoplos.,Pyrotech.2005,30,191.

19 Stierstorfer,J.; Klapötke,T.M.; Hammerl,A.; Chapman,R.D.Z.Anorg.Allg.Chem.2008,634,1051.

20 Chung,G.; Schmidt,M.W.; Gordon,M.S.J.Phys.Chem.2000,104,5647.

21 Wang,L.-J.; Li,S.; Li,Q.-S.J.Comput.Chem.2001,22,1334.

22 Gagliardi,L.; Orlandi,G.; Evangelistil,S.; Roos,B.O.J.Chem.Phys.2001,114,10733.

23 Wu,H.-S.; Xu,X.-H.; Jiao,H.-J.Chem.Phys.Lett.2005,412,299.

24 Parr,R.G.; Yang,W.Density Functional Theory of Atoms and Molecules,Oxford University Press,New York,1989,p.58.

25 Fletcher,R.; Powell,M.J.D.Comput.J.1963,6,163.26 Schlegel,H.B.J.Comp.Chem.1982,3,214.

27 Weinhold,F.In Encyclopedia of Computational Chemistry,Eds.: Schleyer,N.L.; Allinger,T.; Clark,J.; Gasteiger,P.A.; Kollman,H.F.; Schaefer III.,Schreiner,P.R.,John Wiley & Sons,Chichester,U.K.1998,p.1792.

28 Curtiss,L.A.; Redfern,P.C.; Smith,B.J.; Radom,L.J.Chem.Phys.1996,104,5152.

29 Curtiss,L.A.; Raghavachari,K.; Redfern,P.C.J.Chem.Phys.1997,106,1063.

30 Ochterski,J.W.; Petersson,G.A.; Wiberg,K.B.J.Am.Chem.Soc.1995,117,11299.

31 Qiu,L.; Xiao,H.-M.Chin.J.Energ.Mater.2006,14,158 (in Chinese).

(邱玲,肖鹤鸣,含能材料,2006,14,158.)

32 Qiu,L.; Xiao,H.-M.; Ju,X.-H.; Gong,X.-D.Acta Chim.Sinica 2005,63,377 (in Chinese).

(邱玲,肖鹤鸣,居学海,贡雪东,化学学报,2005,63,377.)

33 Guo,Y.-X.; Zhang,H.-S.Expl.Shock Waves 1983,3,56 (in Chinese).

(国迂贤,张厚生,爆炸与冲击,1983,3,56.)

34 Frisch,M.J.; Trucks,G.W.; Schlegel,H.B.Gaussian 03,Revision A.01.,Gaussian Inc.,Pittsburgh,PA,2003.

35 Fan,Q.T.M.S.Thesis,Beijing University of Technology,Beijing,2008 (in Chinese).

(凡庆涛,硕士论文,北京理工大学,北京,2008.)

36 Reed,A.E.; Weinstock,R.B.; Weinhold,F.J.Chem.Phys.1985,83,735.

37 Denffer,M.; Klapötke,T.M.; Sabaté,C.M.Z.Anorg.Allg.Chem.2008,634,2575.

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叠氮唑类高氮含能化合物的理论研究

Theoretical Studies of Azide-Azole Nitrogen-Rich Energetic Compounds

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