A constitutive model for the non-shock ignition and mechanical response of high explosives
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Blaine W. Asay | Joel G. Bennett | K. S. Haberman | J. N. Johnson | James N. Johnson | J. Bennett | B. Asay | K. Haberman | Keith S. Haberman
[1] C. Tarver,et al. Delayed detonation in propellants from low-velocity impact , 1981 .
[2] H. Saunders,et al. Finite element procedures in engineering analysis , 1982 .
[3] G. M. Swallowe,et al. Ignition mechanisms of explosives during mechanical deformation , 1982, Proceedings of the Royal Society of London. A. Mathematical and Physical Sciences.
[4] C. Morris,et al. Los Alamos shock wave profile data , 1982 .
[5] J. K. Dienes,et al. Frictional hot-spots and propellant sensitivity , 1983 .
[6] P. Howe,et al. An Experimental Investigation of the Role of Shear in Initiation of Detonation by Impact , 1986 .
[7] J. N. Johnson,et al. A constitutive model for the dynamic response of brittle materials , 1990 .
[8] S. M. Walley,et al. Hot-spot ignition mechanisms for explosives and propellants , 1992, Philosophical Transactions of the Royal Society of London. Series A: Physical and Engineering Sciences.
[9] J. Field. HOT SPOT IGNITION MECHANISMS FOR EXPLOSIVES , 1992 .
[10] P. B. Butler,et al. Hot-spot ignition of condensed phase energetic materials , 1996 .
[11] J. K. Dienes,et al. A Unified Theory of Flow, Hot Spots, and Fragmentation with an Application to Explosive Sensitivity , 1996 .
[12] Blaine W. Asay,et al. Speckle photography during dynamic impact of an energetic material using laser-induced fluorescence , 1997 .