Investigation of the microstructure of energetic crystals by means of X-ray powder diffraction

Herrmann, Michael; Fietzek, H.

doi:10.1154/1.1913709

Cited by 14 publications

(7 citation statements)

References 7 publications

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“…The data were evaluated according to Williamson and Hall [3] by plotting reciprocal peak widths versus reciprocal lattice distances, and the root mean square strains were estimated from slopes of regression lines. Figure 1 yields different levels and runs of curves, and a bend of the HMX curve around the reciprocal lattice distance 0.3 1/Å, so far confirming previous results [10]. Linear regression lines b* = a d*+b fitted to selected regions of the curves are plotted in Figures 2 and 3 and results of the fits are summarized in Table 1.…”

Section: Experimental and Evaluationsupporting

confidence: 84%

“…As the investigations revealed significant line broadening caused by low absorption of the nitramines, penetration depths have been confined by preparing thin particle layers. Thus, characteristic line broadening was found to distinguish HMX from RDX, and results have been discussed in terms of dislocations and twins [10]. The makeshift preparation technique, however, limited the accuracy and the method was successful only if powders provide sufficient orientation statistics, which is not the case for many crystallized powders.…”

Section: Application On Explosivesmentioning

confidence: 99%

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Microstructure of Energetic Particles Investigated by X‐ray Powder Diffraction

Herrmann

2005

Part & Part Syst Charact

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Incorporation of improved particle qualities reduces the sensitivity of plastic bonded explosives. The mechanisms that cause this effect are far from being clear. Investigations were made using Powder X‐ray Diffraction for the characterization of the microstructure of energetic cyclic nitramines Hexogen (RDX (C3H6N6O6)) and Octogen (HMX (C4H8N8O8)), respectively, including reduced sensitivity and conventional samples. The investigations show that qualities can be distinguished in terms of particle size and micro strain by means of powder X‐ray diffraction. Problems originating from low absorbance or poor orientation statistics of coarse powders have been overcome using advanced measuring techniques. The results are so far interesting for practical applications, e.g., the investigation of slightly absorbing powders (e.g., pharmaceutics, cosmetics, explosives) or coarse crystalline powders by means of diffractometry. The investigations revealed that sensitivity of RDX correlates with crystallite size, where insensitive particles consist of larger and fewer crystallites than the conventional product. The HMX qualities were found to be micro strain and crystallite size driven.

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Section: Experimental and Evaluationsupporting

confidence: 84%

Section: Application On Explosivesmentioning

confidence: 99%

Microstructure of Energetic Particles Investigated by X‐ray Powder Diffraction

Herrmann

2005

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“…For a 3 days storage of the RDX samples in ultrahigh vacuum, this leads to a total mass of sublimed RDX of 17 ng. For an area of 100 × 100 μm 2 , this corresponds to a sublimation of a layer of ∼1-μm thickness (density of RDX is 1.82 g cm −3 , thickness of one molecular layer ∼1 nm; this latter value is an approximate value based on the lattice constants of the orthorhombic crystal structure of RDX: a = 13.182, b = 11.574 and c = 10.709Å; Herrmann & Fietzek, 2005). The estimated value for the sublimed layer thickness of ∼1 μm appears to be in the same range as the surface features that can be observed in Figure 11, indicating that sublimation of the RDX in ultrahigh vacuum can be a realistic explanation.…”

Section: Optical Microscopymentioning

confidence: 99%

Microscopic characterization of defect structure in RDX crystals

Bouma¹,

Duvalois²,

Heijden

2013

Journal of Microscopy

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Summary Three batches of the commercial energetic material RDX, as received from various production locations and differing in sensitivity towards shock initiation, have been characterized with different microscopic techniques in order to visualize the defect content in these crystals. The RDX crystals are embedded in an epoxy matrix and cross‐sectioned. By a treatment of grinding and polishing of the crystals, the internal defect structure of a multitude of energetic crystals can be visualized using optical microscopy, scanning electron microscopy and confocal scanning laser microscopy. Earlier optical micrographs of the same crystals immersed in a refractive index matched liquid could visualize internal defects, only not in the required detail. The combination of different microscopic techniques allows for a better characterization of the internal defects, down to inclusions of approximately 0.5 μm in size. The defect structure can be correlated to the sensitivity towards a high‐amplitude shock wave of the RDX crystals embedded in a polymer bonded explosive. The obtained experimental results comprise details on the size, type and quantity of the defects. These details should provide modellers with relevant and realistic information for modelling defects in energetic materials and their effect on the initiation and propagation of shock waves in PBX formulations.

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“…Mechanical tests revealed the twinning, cleavage, and defect structure of single-crystal HMX. , Microcosmic detection methods such as X-ray diffraction (XRD) were also applied to study the microstructure in HMX. Enhanced peak broadening of XRD patterns is found in HMX compared to other nitramines such as RDX because of twinning. , However, the mechanism of crystal fracture for the HMX-based polymer-bonded explosive (PBX) is still puzzling.…”

Section: Introductionmentioning

confidence: 99%

Acceleration of δ- to β-HMX-D8 Phase Retransformation with D₂O and Intergranular Strain Evolution in a HMX-Based Polymer-Bonded Explosive

Liu

Bai

et al. 2019

J. Phys. Chem. C

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3,5,3,5, is one of the most widely used explosives. Problems about phase state and unrecoverable damage are significant in the application of HMX and HMX-based polymer-bonded explosive (PBX). Recently, the acceleration of δto β-HMX retransformation in humid atmosphere was reported. However, the function of water was not well understood. In this paper, we studied the mixed phase during δto β-HMX-d8 retransformation with neutron diffraction. Evidence of γ-HMX-d8 is specially focused to estimate whether the hydrated phase is part of the δto βphase retransformation. Besides, in situ high-pressure neutron diffraction of HMX-based PBX was performed to study the evolution of intergranular strains in special structures such as twin plane, cleavage planes, and slip systems. We observed an abnormal release of strain on certain planes under applied pressure which had not been reported. This abnormal phenomenon was considered to explain the formation of microcracks in HMX.

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Investigation of the microstructure of energetic crystals by means of X-ray powder diffraction

Cited by 14 publications

References 7 publications

Microstructure of Energetic Particles Investigated by X‐ray Powder Diffraction

Microstructure of Energetic Particles Investigated by X‐ray Powder Diffraction

Microscopic characterization of defect structure in RDX crystals

Acceleration of δ- to β-HMX-D8 Phase Retransformation with D₂O and Intergranular Strain Evolution in a HMX-Based Polymer-Bonded Explosive

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Investigation of the microstructure of energetic crystals by means of X-ray powder diffraction

Cited by 14 publications

References 7 publications

Microstructure of Energetic Particles Investigated by X‐ray Powder Diffraction

Microstructure of Energetic Particles Investigated by X‐ray Powder Diffraction

Microscopic characterization of defect structure in RDX crystals

Acceleration of δ- to β-HMX-D8 Phase Retransformation with D2O and Intergranular Strain Evolution in a HMX-Based Polymer-Bonded Explosive

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Acceleration of δ- to β-HMX-D8 Phase Retransformation with D₂O and Intergranular Strain Evolution in a HMX-Based Polymer-Bonded Explosive