2013
DOI: 10.1063/1.4792001
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Ignition criterion for heterogeneous energetic materials based on hotspot size-temperature threshold

Abstract: A criterion for the ignition of granular explosives (GXs) and polymer-bonded explosives (PBXs) under shock and non-shock loading is developed. The formulation is based on integration of a quantification of the distributions of the sizes and locations of hotspots in loading events using a cohesive finite element method (CFEM) developed recently and the characterization by Tarver et al. [C. M. Tarver et al., "Critical conditions for impact-and shock-induced hot spots in solid explosives," J. Phys. Chem. 100, 579… Show more

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Cited by 86 publications
(54 citation statements)
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References 52 publications
(75 reference statements)
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“…The details obtained on the defects present in the examined RDX crystals can be used to further refine the modelling of energetic composite materials. Lately, significant steps forward have been achieved in describing the heterogeneity of energetic composite materials like PBXs, for example, by developing algorithms to create polydisperse packs of nonspherical shapes of granular explosives (Stafford & Jackson, 2010), by including the effect of metal particles on the deformationinduced heating of an explosive composite (Chakravarthy et al, 2013) and by modelling the hot-spot formation in granular and in PBXs (Handley, 2011;Barua et al, 2013). In the hot-spot modelling, mechanical loading of energetic composites cause frictional dissipation as a result of grain fracture or due to interparticle contacts, leading to local temperature increases that act as hot spots.…”
Section: Cslmmentioning
confidence: 99%
“…The details obtained on the defects present in the examined RDX crystals can be used to further refine the modelling of energetic composite materials. Lately, significant steps forward have been achieved in describing the heterogeneity of energetic composite materials like PBXs, for example, by developing algorithms to create polydisperse packs of nonspherical shapes of granular explosives (Stafford & Jackson, 2010), by including the effect of metal particles on the deformationinduced heating of an explosive composite (Chakravarthy et al, 2013) and by modelling the hot-spot formation in granular and in PBXs (Handley, 2011;Barua et al, 2013). In the hot-spot modelling, mechanical loading of energetic composites cause frictional dissipation as a result of grain fracture or due to interparticle contacts, leading to local temperature increases that act as hot spots.…”
Section: Cslmmentioning
confidence: 99%
“…Wherever possible, fundamental information from experiment is also used. For energetic materials, this sequential approach is the one most commonly used for multiscale model development [5][6][7][8][9][10][11][12][13][14][15][16].…”
Section: Introductionmentioning
confidence: 99%
“…Electronic mail: dlott@illinois.edu crostructure, the method of energy input, and the hot spot sizes and lifetimes. 6,7 As a benchmark, it has been shown by calorimetry that RDX decomposes with a strong exotherm when heated to 530 K. 8 Almost all previous observations of hot spots in EM relied on visible emission techniques such as high-speed photography. 1,2,[9][10][11][12] Notable exceptions were two 1992 studies by Woody, 13,14 who used a fast IR detector array to obtain single time-gated images of shear bands created in salt crystals subjected to low-velocity impacts, and more recent works by Dickson and co-workers 15 and Perry and co-workers, 16 who studied impacted EM with a combination of visible and IR imaging.…”
Section: Introductionmentioning
confidence: 99%