[1] 石城宽,许湘宁,董成.内嵌叠氮化铜碳纳米管复合含能材料的制备与表征[J].爆破器材,2019,48(5):19-23. SHI C K,XU X N,DONG C.Preparation and characterization of a composite energetic material of carbon nanotubes embedded with copper azide [J].Explosive Materials,2019,48(5):19-23.(in Chinese) [2] WANG Q Y, HAN J M, ZHANGY Y, et al. Fabrication of copper azide film through metal-organic framework for micro-initiator applications[J]. ACS Applied Materials & Interfaces, 2019, 11(8): 8081-8088. [3] YU Q X, LI M Y, ZENG Q X, et al. Copper azide prepared by reaction of hollow CuO microspheres with moist HN3 gas[J]. Materials Letters, 2018, 224: 18-21. [4] PELLETIER V, BHATTACHARYYA S, KNOKE I, et al. Copper azide confined inside templated carbon nanotubes[J]. Advanced Functional Materials, 2010, 20(18): 3168-3174. [5] LIU X W, LI T T, HU Y, et al. Copper azide nanowires@rGO energetic composite with low electrostatic sensitivity[J]. Journal of Physics: Conference Series, 2020, 1507(2):022004. [6] 耶金,杨娜,程彦飞.PDA@Cu(N3)2核壳结构起爆药的制备及表征[J].火工品,2020(6):26-29. YE J,YANG N,CHENG Y F.Preparation and characterization of PDA@Cu(N3)2core shell primary explosive [J].Initiators & Pyrotechnics,2020(6):26-29.(in Chinese) [7] ZHANG L, ZHANG F, WANG Y L. In-situ preparation of copper azide by direct ink writing[J], Materials Letters, 2019, 238: 130-133. [8] ZHANG F, WANG Y L, BAI Y W, et al. Preparation and characterization of copper azide nanowire array[J]. Materials Letters, 2012, 89: 176-179. [9] YU C P, ZHANG W C, GUO S Y, et al. A safe and efficient liquid-solid synthesis for copper azide films with excellent electrostatic stability[J]. Nano Energy, 2019, 66: 104135. [10] XU R, YAN Z Z, YANG L, et al. Nanoscale homogeneous energetic copper azides@ porous carbon hybrid with reduced sensitivity and high ignition ability[J]. ACS Applied Materials & Interfaces, 2018, 10(26): 22545-22551. [11] 张程刚,胡艳,郭锐,等.填充叠氮化铜的碳纳米管纳米材料的制备研究[J].爆破器材,2017,46(1):1-5. ZHANG C G,HU Y,GUO R, et al.Preparation of copper azidefilled carbon nanotubes [J].Explosive Materials,2017,46(1): 1-5.(in Chinese) [12] 王燕兰,张方,张蕾,等.原位反应法制备填充叠氮化铜的碳纳米管阵列[J].含能材料,2016,24(4):386-392. WANG Y L,ZHANG F,ZHANG L, et al.In-situ preparation of carbon nanotubes array confined with copper azide[J].Chinese Journal of Energetic Materials,2016,24(4):386-392.(in Chinese) [13] 李娜,许建兵,叶迎华,等.三维多孔微纳米结构叠氮化铜的原位合成及表征[J].火炸药学报,2015,38(4):63-66. LI N,XU J B,YE Y H, et al.In-situ synthesis and characterization of three-dimensional porous micro-nano-structured copper azide[J].Chinese Journal of Propellant and Explosives,2015,38(4):63-66.(in Chinese) [14] WANG Q Y, FENG X, WANG S, et al. Explosives: metal-organic framework templated synthesis of copper azide as the primary explosive with low electrostatic sensitivity and excellent initiation ability[J]. Advanced Materials, 2016, 28(28):5766. [15] SHEN Y, XU J B, LI N, et al. A micro-initiator realized by in-situ synthesis of three-dimensional porous copper azide and its ignition performance[J]. Chemical Engineering Journal, 2017, 326: 1116-1124. [16] YU Q X, LI M Y, ZENG Q X, et al. Copper azide fabricated by nanoporous copper precursor with proper density[J]. Applied Surface Science, 2018, 442: 38-44. [17] MATHEY Y, GREIG D R, SHRIVER D F. Variable-temperature Raman and infrared spectra of the copper acetate dimer Cu2(O2CCH3)4(H2O)2 and its derivatives[J].Inorganic Chemistry, 1982,21:3409-3413. [18] ITAB Y, SECOU S, THIERRY D,et al. Forward looking analysis approach to assess copper acetate thermal decomposition reaction mechanism[J]. American Journal of Analytical Chemistry, 2019,10(5): 153-170. [19] LI Z M, ZHOU M R, ZHANG T L, et al. The facile synthesis of graphene nanoplatelet-lead styphnate composites and their depressed electrostatic hazards[J]. Journal of Materials Chemistry A, 2013(41): 12710-12714.
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