The reactive flow evolution of the polymer-bonded explosive PBX 9502: Experiments and model validation in extreme pressure regimes

Burns, M. J.; Chiquete, C.; Espy, M. A.

doi:10.1063/5.0168598

Journal of Applied Physics

2023

DOI: 10.1063/5.0168598

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The reactive flow evolution of the polymer-bonded explosive PBX 9502: Experiments and model validation in extreme pressure regimes

M. J. Burns,

C. Chiquete,

M. A. Espy

Abstract: The shock-to-detonation transition properties of the triaminotrinitrobenzene based PBX 9502 high explosive (HE) are experimentally and computationally explored in extremely high input pressure conditions. These include both slightly sub-Chapman–Jouguet and overdriven input pressure conditions, namely, ∼25 and ∼31 GPa, respectively. Our experiments capture the transient buildup of a shock-induced reaction via measurement of HE and polymethyl methacrylate window interface particle velocity profiles for a variety… Show more

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2024

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Cited by 4 publications

References 26 publications

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Simulation and fabrication of reactive metamaterials for controllable energy response

Ichiyama,

Stanisha,

Scarpelli

et al. 2024

Propellants Explo Pyrotec

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Simulations and experiments were conducted to control the shock‐to‐detonation transition by energy trapping in localized regions of nitromethane that contained arrays of embedded dense particles (tantalum rods). The localizations were additively manufactured and designed with simulations carried out with ALE3D, that used the ignition and growth reactive flow model for the explosive. Modelling demonstrated enhanced reactivity when the tantalum rods were present, leading to a detonation that otherwise did not occur for the same strength shock without rods. Experiments that confirmed predictions of the simulation were conducted using Fritz plane wave lenses to drive various input shocks into the system. Photon doppler velocimetry was the primary diagnostic used to measure shock input and reaction progression. These results suggest that it is possible design explosives to localize sensitivity to shock loading within an insensitive material increasing the overall safety of fielded energetic materials.

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Simulation and fabrication of reactive metamaterials for controllable energy response

Ichiyama,

Stanisha,

Scarpelli

et al. 2024

Propellants Explo Pyrotec

View full text Add to dashboard Cite

show abstract

Effect of mixed carbon phase state on detonation parameters and reaction zone of explosives under extreme condition

Liu,

Duan,

Cao

et al. 2024

Journal of Applied Physics

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A precise description of the thermodynamic states of gaseous and solid detonation products is essential when using thermodynamic calculations to determine the detonation performance and destructive power of explosives. For high oxygen-lean explosives (the oxygen contained in explosives is insufficient to completely oxidize combustible elements and excess solid carbon will be generated in the detonation products), the phase state of solid carbon product affects the Chapman–Jouguet (CJ) detonation performance parameters, reaction zone, and energy release process. However, the recovery of detonation products demonstrates that the actual detonation carbon product is primarily a mixed state of diamond/graphite stack, as opposed to the existing thermodynamic codes, which essentially treat detonation carbon as single-phase carbon. To understand the thermodynamic effect of the mixed carbon phase state on the non-ideal detonation behavior, in this work, the matching relationship among the VINET equation of state parameters, thermodynamic potential parameters of the solid products of the equivalent system and the phase mixed system was constructed by using the nonlinear fitting method. The relationship between the carbon phase composition at the CJ point and the explosive composition structure was researched. Investigations were conducted into how the mixed carbon phase affected the volume and content of gas products as well as the composition at CJ points. Diamond formation in products is good for enhancing explosive's working capacity. Based on mixed-state potential parameters, the correlation mechanism between the mixed carbon phase and the chemical reaction zone was investigated, and it was found that intramolecular carbon/intermolecular carbon and more detonation graphite/diamond products all would lead to the extension of the reaction zone.

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Numerical study on the shock-induced ejecta formation from a grooved aluminum surface: The effect of groove size

Liang,

Wu,

Shao

et al. 2024

Physics of Fluids

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The structure of surface defects is one of the primary focuses in exploring the mechanism behind microjetting phenomena. However, the influence of defect size on microjets remains understudied. This work investigated the correlation between shock-induced microjets and surface defect scales under continuous approximation with the smoothed particle hydrodynamics method. The physical properties of microjets from generation to fragmentation were analyzed in detail. A relationship between the mass of different parts of the microjet and the defect size was established. The results indicate that the length of microjets and the jetting head velocity increase with the increase in the defect sizes. The jetting head velocity increases significantly when the defect depth is less than 4 μm, and the increase slows down when the defect depth is greater than 4 μm. This is attributed to the pressure and energy variations in the defect surface layer. A transition in the mass distribution of the microjet occurs when the defect depth reaches 7 μm. The jetting factor exhibits a trend of decreasing first and then increasing with the enlargement of defect size. The time of microjet fragmentation shows a proportional relationship with the defect size. By statistically analyzing the distribution of microjet fragmentation aggregates, it is found that the dispersal degree of microjet fragmentation aggregate sizes increases with defect size. This research reveals the correlation between the microjet and defect size.

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The reactive flow evolution of the polymer-bonded explosive PBX 9502: Experiments and model validation in extreme pressure regimes

Cited by 4 publications

References 26 publications

Simulation and fabrication of reactive metamaterials for controllable energy response

Simulation and fabrication of reactive metamaterials for controllable energy response

Effect of mixed carbon phase state on detonation parameters and reaction zone of explosives under extreme condition

Numerical study on the shock-induced ejecta formation from a grooved aluminum surface: The effect of groove size

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