http://orcid.org/0000-0002-5448-5854
References
- Ayoman, E., and S. G. Hosseini. 2016. Synthesis of CuO nanopowders by high-energy ball-milling method and investigation of their catalytic activity on thermal decomposition of ammonium perchlorate particles. Journal of Thermal Analysis and Calorimetry 123:1213–24.
- Cai, Y. 1987. Combustion mechanism of double-base propellants with lead burning rate catalysts. Propellants Explosives Pyrotechnics 12:209–14.
- Camp, A., and F. Cresenzo. 1964. Copper and lead burning rate modifiers for double base propellants containing aluminium. Usp 3:138–499.
- Caputo, T., L. Lisi, and R. Pirone. 2007. Kinetics of the preferential oxidation of CO over CuO/CeO2 catalysts in H2-rich gases. Industrial & Engineering Chemistry Research 46:6793–800.
- Chen, L., L. Li, and G. Li. 2008. Synthesis of CuO nanorods and their catalytic activity in the thermal decomposition of ammonium perchlorate. Journal of Alloys and Compounds 464:532–36.
- Delogu, F. 2005. Structural and energetic properties of unsupported Cu nanoparticles from room temperature to the melting point: Molecular dynamics simulations. Physical Review B 72:205418.
- Fan, R. H., H. L. Lü, and K. N. Sun. 2006. Kinetics of thermite reaction in Al-Fe2O3 system. Thermochimica Acta 440:129–31.
- Gao, J. M., L. Wang, and H. J. Yu. 2011. Recent research progress in burning rate catalysts. Propellants Explosives Pyrotechnics 36:404–09.
- Ghosh, K., C. S. Pant, and R. Sanghavi. 2009. Studies on triple base gun propellant based on two energetic azido esters. Journal of Energetic Materials 27:40–50.
- Hao, G., J. Liu, and H. Liu. 2016. Cu-Cr-Pb nanocomposites. Journal of Thermal Analysis and Calorimetry 123:263–72.
- Hao, G., J. Liu, and Q. Liu. 2017. Facile preparation of AP/Cu(OH)2 core-shell nanocomposites and its thermal decomposition behavior. Propellants Explosives Pyrotechnics 42:947–52.
- Hewkin, D. J., J. A. Hicks, and J. Powling. 2007. The combustion of nitric ester-based propellants: ballistic modification by lead compounds. Combustion Science and Technology 2:307–27.
- Hosseini, S. G., and R. Abazari. 2015. A facile one-step route for production of CuO, NiO, and CuO-NiO nanoparticles and comparison of their catalytic activity for ammonium perchlorate decomposition. Rsc Advances 5:96777–84.
- Khakbiz, M., and F. Akhlaghi. 2009. Synthesis and structural characterization of Al-B4C nano-composite powders by mechanical alloying. Journal of Alloys and Compounds 479:334–41.
- Lee, J. G., S. Hong, and J. Park. 2010. High energy ball-mill behavior of titania+ hydroxyapatite composite nano-powders. Materials Characterization 61:1290–93.
- Li, S. F. 1998. The micro-structure observation of quenched surface in double-base propellant with lead salt. Combustion Science and Technology 133:395–401.
- Palaiah, R. S. 2001. Influence of metal salts of 4-(2, 4, 6-trinitroanilino) benzoic acid on the burnining rate of double base propellants. Journal of Energetic Materials 19:339–47.
- Raj, D. M. A., A. D. Raj, and A. A. Irudayaraj. 2014. Facile synthesis of rice shaped CuO nanostructures for battery application. Journal of Materials Science: Materials in Electronics 25:1441–45.
- Ren, H., Y. Liu, and Q. Jiao. 2010. Preparation of nanocomposite PbO•CuO/CNTs via microemulsion process and its catalysis on thermal decomposition of RDX. Journal of Physics and Chemistry of Solids 71:149–52.
- Sharma, J. K., M. S. Akhtar, and S. Ameen. 2015. Green synthesis of CuO nanoparticles with leaf extract of calotropis gigantea and its dye-sensitized solar cells applications. Journal of Alloys and Compounds 632:321–25.
- Sharma, J. K., P. Srivastava, and G. Singh. 2015. Biosynthesized NiO nanoparticles: Potential catalyst for ammonium perchlorate and composite solid propellants. Ceramics International 41:1573–78.
- Wei, T., Y. Zhang, and K. Xu. 2015. Catalytic action of nano Bi2WO6 on thermal decompositions of AP, RDX, HMX and combustion of NG/NC propellant. Rsc Advances 5:70323–28.
- Woo, D., B. Sneed, and F. Peerally. 2013. Synthesis of nanodiamond-reinforced aluminum metal composite powders and coatings using high-energy ball milling and cold spray. Carbon 63:404–15.
- Xu, X., T. Nishimura, and N. Hirosaki. 2007. Fabrication of a Nano-Si3N4/Nano-C composite by high-energy ball milling and spark plasma sintering. Journal of the American Ceramic Society 90:1058–62.
- Yan, Q. L., X. J. Li, and Y. Wang. 2009. Combustion mechanism of double-base propellant containing nitrogen heterocyclic nitroamines (I): The effect of heat and mass transfer to the burning characteristics. Combustion and Flame 156:633–41.
- Yi, J. H., F. Q. Zhao, and W. L. Hong. 2010. Effects of Bi-NTO complex on thermal behaviors, nonisothermal reaction kinetics and burning rates of NG/TEGDN/NC propellant. Journal of Hazardous Materials 176:257–61.