[1] BOWDE F P, YOFFE A D. Initiation and growth of explosions in liquids and solids[M]. Cambridge, UK: Cambridge University Press, 1951. [2] CHAUDHRI M M. Stab initiation of explosions[J]. Nature, 1976, 263(5573):121-122. [3] CHAUDHRI M M. The initiation of fast decomposition in solid explosives by fracture, plastic flow, friction and collapsing voids[C]∥Proceedings of the 9th Symposium International on Detonation. Portland, OR, US: Office of Naval Research, 1989: 331-339. [4] FREY R B. Cavity collapse in energetic materials [C]∥Proceedings of the 8th Symposium (International) on Detonation. Silver Spring, MD, US: Office of Naval Research, 1985:68-80. [5] FIELD J E. Hot spot ignition mechanisms for explosives[J]. Accounts of Chemical Research, 1992, 25(11):489-496. [6] MENIKOFF R. On beyond the standard model for high explosives challenges & obstacles to surmount[J]. AIP Conference Proceedings, 2009, 1195(18):18-25. [7] CHAUDHRI M M, FIELD J E. The role of rapidly compressed gas pockets in the initiation of condensed explosives[J]. Proceedings of the Royal Society A: Mathematical and Physical Sciences, 1974, 340(1620):113-128. [8] KHASAINOV B A, BORISOV A A, ERMOLAEV B S, et al. Two-phase visco-plastic model of shock initiation of detonation in high density pressed explosives[C]∥Proceedings of the 7th Symposium (International) on Detonation. Annapolis, MD, US: Naval Weapons Center, 1981:435-447. [9] MADER C. Numerical modeling of explosives and propellants[M]. Boca Raton, FL, US: CRC Press, 1998:172. [10] DUARTE C A, HAMED A, DRAKE J D, et al. Void collapse in shocked β-HMX single crystals: simulations and experiments[J]. Propellants, Explosives, Pyrotechnics, 2020, 45(2):243-253. [11] ESCAURIZA E M, DUARTE J P, CHAPMAN D J, et al. Collapse dynamics of spherical cavities in a solid under shock loading[J]. Scientific Reports, 2020, 10(1):8455. [12] RAI N K, ESCAURIZA E M, EAKINS D E, et al. Mechanics of shock induced pore collapse in poly (methyl methacrylate) (PMMA): comparison of simulations and experiments[J]. Journal of the Mechanics and Physics of Solids, 2020, 143:104075. [13] MENIKOFF R. Pore collapse and hot spots in HMX[J]. AIP Conference Proceedings, 2004, 706:393-396. [14] CHITANVIS S M. Hotspot mechanisms in shock-melted explosives[J]. AIP Conference Proceedings, 2004, 706:319-322. [15] TRAN L, UDAYKUMAR H S. Simulation of void collapse in an energetic material, part 1: inert case[J]. Journal of Propulsion and Power, 2006, 22(5):947-958. [16] TRAN L, UDAYKUMAR H S. Simulation of void collapse in an energetic material, part 2: reactive case[J]. Journal of Propulsion and Power, 2006, 22(5):959-974. [17] NAJJAR F M, HOWARD W M, FRIED L E. Computational study of 3-D hot-spot initiation in shocked insensitive high-explosive[J]. AIP Conference Proceedings, 2012, 1426(1):255-258. [18] KAPAHI A, UDAYKUMAR H S. Three-dimensional simulations of dynamics of void collapse in energetic materials[J]. Shock Waves, 2015; 25(2):177-187. [19] MICHAEL L, NIKIFORAKIS N. The evolution of the temperature field during cavity collapse in liquid nitromethane. Part I: inert case[J]. Shock Waves, 2019, 29(1):153-172. [20] MICHAEL L, NIKIFORAKIS N. The evolution of the temperature field during cavity collapse in liquid nitromethane. Part II: reactive case[J]. Shock Waves, 2019, 29(1):173-191. [21] JACKSON T L, BUCKMASTER J D, ZHANG J, et al. Pore collapse in an energetic material from the micro-scale to the macro-scale[J]. Combustion Theory and Modelling, 2015, 19(3): 347-381. [22] KAPILA A K, SCHWENDEMAN D W, GAMBINO J R, et al. A numerical study of the dynamics of detonation initiated by cavity collapse[J]. Shock Waves, 2015, 25(6):545-572. [23] KAPAHI A, UDAYKUMAR H S. Dynamics of void collapse in shocked energetic materials: physics of void-void interactions[J]. Shock Waves, 2013; 23(6):537-558. [24] RAI N K, UDAYKUMAR H S. Void collapse generated meso-scale energy localization in shocked energetic materials: Non-dimensional parameters, regimes, and criticality of hotspots[J]. Physics of Fluids, 2019, 31(1):016103. [25] 洪滔, 王裴. 炸药中热点形成的数值模拟[J]. 含能材料, 2004, 12(增刊1):509-513. HONG T, WANG P. Numerical simulation of formation of hot spot in high explosive[J]. Energetic Materials, 2004, 12(S1):509-513. (in Chinese) [26] 刘新桥, 王成. 凝聚相炸药爆轰波冲击空穴塌陷过程的高精度数值模拟[J]. 北京理工大学学报, 2016, 36(4):354-358. LIU X Q, WANG C. High resolution numerical simulation of detonation wave shock-induced void collapse in condensed explosives[J]. Transactions of Beijing Institute of Technology, 2016, 36(4):354-358. (in Chinese) [27] LEVESQUE G A, VITELLO P. The effect of pore morphology on hot spot temperature[J]. Propellants, Explosives, Pyrotechnics, 2015, 40(2):303-308. [28] RAI N K, SCHMIDT M J, UDAYKUMAR H S. Collapse of elongated voids in porous energetic materials: effects of void orientation and aspect ratio on initiation[J]. Physical Review Fluids, 2017, 2(4):043201. [29] SPRINGER H K, BASTEA S, NICHOLS A L,et al. Modeling the effects of shock pressure and pore morphology on hot spot mechanisms in HMX[J]. Propellants, Explosives, Pyrotechnics, 2018, 43(8):805-817. [30] MA D Z, CHEN P W, ZHOU Q, et al. Ignition criterion and safety prediction of explosives under low velocity impact[J]. Journal of Applied Physics, 2013, 114(11):113505. [31] BARENBLATT G I. Scaling, self-similarity, and intermediate asymptotics[M]. Cambridge, UK: Cambridge University Press, 1996. [32] KULIKOVSKII A G, POGORELOV N V, SEMENOV A Y. Mathematical aspects of numerical solution of hyperbolic systems[M]∥FEY M, JELTSCH R. Hyperbolic Problems: Theory, Numerics, Applications. Basel, Switzerland:Springer Basel AG, 2000:4. [33] HOLMQUIST T J, JOHNSON G R. Determination of constants and comparison of results for various constitutive models[J]. Journal de Physique IV, 1991, 1(C3):853-860.
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