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1. Multi-Task Multi-Fidelity Learning of Properties for Energetic Materials

Author

Appleton, Robert J., Klinger, Daniel, Lee, Brian H., Taylor, Michael, Kim, Sohee, Blankenship, Samuel, Barnes, Brian C., Son, Steven F., and Strachan, Alejandro

Subjects
Computer Science - Machine Learning, Condensed Matter - Materials Science
Abstract

Data science and artificial intelligence are playing an increasingly important role in the physical sciences. Unfortunately, in the field of energetic materials data scarcity limits the accuracy and even applicability of ML tools. To address data limitations, we compiled multi-modal data: both experimental and computational results for several properties. We find that multi-task neural networks can learn from multi-modal data and outperform single-task models trained for specific properties. As expected, the improvement is more significant for data-scarce properties. These models are trained using descriptors built from simple molecular information and can be readily applied for large-scale materials screening to explore multiple properties simultaneously. This approach is widely applicable to fields outside energetic materials., Comment: 16 pages, 4 figures, 2 tables

Published
2024

3. Characterization and calibration of a piezo-energetic composite film as a reactive gauge.

Author

Messer, Derek K., Örnek, Metin, Nunes, Cohen T., Paral, Mark W., and Son, Steven F.

Subjects
PROPELLANTS, PRESSURE sensors, DIFLUOROETHYLENE, ALUMINUM films, BINDING agents, CALIBRATION, LEAD zirconate titanate
Abstract

The field of multifunctional energetics encompasses a range of materials including propellants, explosives, and pyrotechnics that possess the ability to be manipulated through various characteristics that can be switched between go and no-go, or those that have controllable energy release levels or have additional functions beyond energetic output. The development of multifunctional energetics harnessing electromechanical or piezoelectric properties of polymeric materials or binder systems has garnered increasing interest in recent years. Among polymers, fluoropolymers such as poly(vinylidene fluoride) (PVDF) and copolymers such as poly(vinylidene fluoride-trifluoroethylene) [P(VDF-TrFE)], which are used as the binder and oxidizer in the energetic formulations, have demonstrated the highest piezoelectric coefficients. In this study, we fabricated piezo-energetic composite films using aluminum nanopowders (10 wt. % active content) as fuel and P(VDF-TrFE) (70/30) as an oxidizer and investigated the piezoelectric response using a small-scale drop weight setup. Additionally, we employed a shaker setup to investigate the response of the films to vibrations. Our findings demonstrate that these piezo-energetic films can replicate the behavior of a commercial PVDF gauge at relatively low-pressure impacts, indicating their potential use as shock or pressure sensors in various fields, as well as an accelerometer gauge. Additionally, aging studies of up to one year indicated minimal loss in the energetic content of the created films, enabling the use of energetic gauges for an extended period. Our findings support the effectiveness of piezo-energetic composite films as pressure sensors or accelerometers and highlight their potential for energetic applications. [ABSTRACT FROM AUTHOR]

Published
2024
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9. The effect of porosity on flexoelectricity in 3D printed aluminum/polyvinylidene fluoride composites.

Author

Hafner, Thomas A., Örnek, Metin, Collard, Diane N., Paral, Mark W., and Son, Steven F.

Subjects
POLYVINYLIDENE fluoride, FLEXOELECTRICITY, POROSITY, STRAINS & stresses (Mechanics), ALUMINUM, PARTICULATE matter, ALUMINUM composites
Abstract

We investigated the relationship between porosity and flexoelectricity for aluminum (Al)/polyvinylidene fluoride (PVDF) composites. Neat PVDF, composites of micron aluminum (μAl)/PVDF, and composites of nano aluminum (nAl)/PVDF were 3D printed, and the flexoelectric response was measured using a cantilever beam test setup. Voids (up to 72.4 mm3) were incorporated into the samples by decreasing the infill percent of the 3D printed material. We found that increasing the porosity via millimeter scale voids incorporated into the infill pattern decreased the average effective flexoelectric coefficient relative to the near full-density (100% infill) control samples. This contrasts with other studies that have shown increasing micron scale porosity increases the flexoelectric coefficient. In addition, we measured higher flexoelectric responses for nAl/PVDF than μAl/PVDF as well as for samples printed by the Hyrel 3D SR printer as opposed to the Ender 3 V2 printer. These results indicate that charge generation due to flexoelectricity can be altered by changing parameters such as porosity, particle size of inclusions, or manufacturing method. Smaller voids and fine particles can induce larger strain gradients than larger inhomogeneities, leading to increased flexoelectric coefficients. A competing effect is that more porosity leads to less materials, which can decrease the flexoelectric coefficient. [ABSTRACT FROM AUTHOR]

Published
2023
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17. Extending Aluminum Hydration Surface Treatments from Nanoparticles to Microparticles

Author

Malek, Mahmuda Ishrat, Collard, Diane N., Son, Steven F., and Pantoya, Michelle L.

Abstract

The combustion mechanism of aluminum (Al) particles depends on the alumina (Al2O3) passivation shell surrounding the metal core. Hydrating Al2O3to synthesize an Al(OH)3shell alters the particle’s reaction mechanism and energy release behavior. While the Al2O3shell of aluminum nanoparticles (nAl) has been successfully hydrated to produce an Al(OH)3–Al shell–core structure, extending shell processing to micrometer-sized aluminum (μAl) particles did not follow the same hydration procedure. The difference in particle surface energy is responsible for the parameters controlling hydration kinetics. The μAl particles with lower surface energy successfully achieved surface hydration by controlling only temperature and time in suspension. The nAl particles, with 91.4% higher surface energy than μAl, required control of aqueous pH to achieve similar surface hydration as μAl. One objective of this study is to identify surface reaction mechanisms that are a function of particle size (and surface energy). A second objective is to assess the feasibility of using surface-hydrated particles for energy-generating applications. This objective is accomplished through accelerated aging tests using thermal equilibrium analysis to investigate particle reactivity and safety tests including electrostatic discharge, impact, and friction sensitivity. Results show that all surface-hydrated particles passed safety testing, but the surface-hydrated nAl experienced significant aging while the μAl particles negligibly aged. An explanation for the distinct aging behavior as a function of particle size is provided and based on hydration kinetics and equilibrium results.

Published
2024
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20. Closed vessel burning rate measurements of composite propellants using microwave interferometry.

Author

Oatman, Shane A., Caito, August A., Klinger, Daniel J., Cooper, James N., Manship, Tim D., and Son, Steven F.

Subjects
SOLID propellants, PRESSURE vessels, MICROWAVE materials, INTERFEROMETRY, PROPELLANTS, MICROWAVES
Abstract

Burning rate as a function of pressure is one of the primary evaluation metrics of solid propellants. Most solid propellant burning rate measurements are made at a nearly constant pressure using a variety of measurement approaches. This type of burning rate data is highly discretized and requires many tests to accurately determine the burning rate response to pressure. It would be more efficient to measure burning rate dynamically as pressures are varied. Techniques used to make transient burning rate measurements are reviewed briefly and initial results using a microwave interferometry (MI) technique are presented. The MI method used in tandem with a closed bomb enables nearly continuous measurement of burning rates for self‐pressurizing burns, capturing burning rate data over a wide range of pressures. This approach is especially useful for characterization of propellants with complex burning behaviors (e. g., slope breaks or mesa burning). The burning rates of three research propellants were characterized over a pressure range of 0.101–24.14 MPa (14–3500 psi). One research propellant exhibited a slope break at a pressure of 6.63 MPa (960 psi). Using MI in a closed pressure vessel, 14 propellant strand burns resulted in a nearly continuous burning rate curve over a pressure range of 0.41–24.13 MPa (60–3500 psi) that reasonably matched conventional burning rate measurements. The development of this technique provides an opportunity to quickly characterize the burning rate curve of solid propellants with greater fidelity and efficiency than traditional quasi‐static pressure testing techniques. [ABSTRACT FROM AUTHOR]

Published
2024
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31. Dielectric breakdown driven by flexoelectric and piezoelectric charge generation as hotspot ignition mechanism in aluminized fluoropolymer films.

Author

Shin, Ju Hwan, Messer, Derek K., Örnek, Metin, Son, Steven F., and Zhou, Min

Subjects
ELECTRIC charge, DIELECTRIC breakdown, ELECTRIC breakdown, FLEXOELECTRICITY, FLUOROPOLYMERS, PIEZOELECTRICITY, IGNITION temperature
Abstract

Using multiphysics simulations and experiments, we demonstrate that dielectric breakdown due to electric charge accumulation can lead to sufficient hotspot development leading to the initiation of chemical reactions in P(VDF-TrFE)/nAl films comprising a poly(vinylidene fluoride-co-trifluoroethylene) binder and nano-aluminum particles. The electric field (E-field) development in the material is driven by the flexoelectric and piezoelectric responses of the polymer binder to mechanical loading. A two-step sequential multi-timescale and multi-physics framework for explicit microscale computational simulations of experiments is developed and used. First, the mechanically driven E-field development is analyzed using a fully coupled mechanical–electrostatic model over the microsecond timescale. Subsequently, the transient dielectric breakdown process is analyzed using a thermal–electrodynamic model over the nanosecond timescale. The temperature field resulting from the breakdown is analyzed to establish the hotspot conditions for the onset of self-sustained chemical reactions. The results demonstrate that temperatures well above the ignition temperatures can be generated. Both experiments and analyses show that flexoelectricity plays a primary role and piezoelectricity plays a secondary role. In particular, the time to ignition and the time to pre-ignition reactions of poled films (possessing both piezoelectricity and flexoelectricity) are ∼10% shorter than those of unpoled films (possessing only flexoelectricity). [ABSTRACT FROM AUTHOR]

Published
2022
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32. The growth and nanothermite reaction of 2Al/3NiO multilayer thin films.

Author

Abere, Michael J., Beason, Matthew T., Reeves, Robert V., Rodriguez, Mark A., Kotula, Paul G., Sobczak, Catherine E., Son, Steven F., Yarrington, Cole D., and Adams, David P.

Subjects
THIN films, KIRKENDALL effect, MULTILAYERED thin films, SPUTTER deposition, MANUFACTURING processes, IGNITION temperature, ACTIVATION energy
Abstract

Nanothermite NiO–Al is a promising material system for low gas emission heat sources; yet, its reactive properties are highly dependent on material processing conditions. In the current study, sputter deposition is used to fabricate highly controlled nanolaminates comprised of alternating NiO and Al layers. Films having an overall stoichiometry of 2Al to 3NiO were produced with different bilayer thicknesses to investigate how ignition and self-sustained, high temperature reactions vary with changes to nanometer-scale periodicity and preheat conditions. Ignition studies were carried out with both hot plate and laser irradiation and compared to slow heating studies in hot-stage x-ray diffraction. Ignition behavior has bilayer thickness and heating rate dependencies. The 2Al/3NiO with λ ≤ 300 nm ignited via solid/solid diffusion mixing (activation energy, Ea = 49 ± 3 kJ/mole). Multilayers having λ≥ 500 nm required a more favorable mixing kinetics of solid/liquid dissolution into molten Al (Ea = 30 ± 4 kJ/mole). This solid/liquid dissolution Ea is a factor of 5 lower than that of the previously reported powder compacts due to the elimination of a passivating Al oxide layer present on the powder. The reactant mixing mechanism between 300 and 500 nm bilayer thicknesses was dependent on the ignition source's heating rate. The self-propagating reaction velocities of 2Al/3NiO multilayers varied from 0.4 to 2.5 m/s. Pre-heating nanolaminates to temperatures below the onset reaction temperatures associated with forming intermediate nickel aluminides at multilayer interfaces led to increased propagation velocities, whereas pre-heating samples above the onset temperatures inhibited subsequent attempts at laser ignition. [ABSTRACT FROM AUTHOR]

Published
2022
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40. Preparation and characterization of multifunctional piezoenergetic polyvinylidene fluoride/aluminum nanocomposite films.

Author

Örnek, Metin, Uhlenhake, Kyle E., Zhou, Yao, Zhang, Bruce, Kalaswad, Matias, Collard, Diane N., Wang, Haiyan, Wang, Qing, and Son, Steven F.

Subjects
ALUMINUM films, POLYVINYLIDENE fluoride, FOURIER transform infrared spectroscopy, DIELECTRIC strength, DIELECTRIC films, ALUMINUM composites, FERROELECTRIC polymers, FLAME temperature
Abstract

We prepared poly(vinylidene fluoride) (PVDF) and aluminum composite dense films using a tape caster and investigated the microstructural, thermal, and electrical properties and the combustion behavior of the films as a function of nano-aluminum (nAl) solids loading (5–30 wt. %). We found that the addition of nAl facilitates the formation of piezoelectric β and γ phases of PVDF as determined by x-ray diffraction and Fourier transform infrared spectroscopy. At higher nAl solid loadings, the lower onset temperature of the pre-ignition and decomposition reactions have been observed. Moreover, the intentionally incorporated porosity into the films slightly affected the thermal decomposition behavior. While the dielectric constant of the films increases with higher nAl content, the dielectric breakdown strength of the films decreases significantly. The critical active nAl content for the films to exhibit self-propagated reaction was determined to be between 10 and 15 wt. %. Thermochemical calculations using the NASA CEA code showed the maximum flame temperature of 1750 °C near the stoichiometric ratio (∼20 wt. %). The burning rate of the films is enhanced drastically at ambient conditions with further addition of nAl. However, the films with active nAl content over 20 wt. % showed lower flame temperatures, which is due to the reduction of hydrofluoric acid gas generation and the incomplete combustion of Al to form aluminum monofluoride (AlF), instead of aluminum fluoride (AlF3) gas. The fabrication of energetic thin films with tunable properties could enable their use in multifunctional energetic material systems. [ABSTRACT FROM AUTHOR]

Published
2022
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42. Evolution of explosively driven flash coatings.

Author

Montoya, Gabriel A., Dean, Joshua, Lawrence, Joseph R., Salyer, Terry R., and Son, Steven F.

Subjects
SURFACE coatings, IMAGE intensifiers, MAGNESIUM oxide, EXPLOSIVES, CIGARETTES, FURAZANS
Abstract

Highspeed Imaging has always been an integral part of explosives research, with detonation velocities regularly reaching speeds greater than 6 km/s and events of interest lasting on the order of ns. Despite the high energy release of explosives during detonation, light production is a common issue when imaging at high rates. To combat this, many techniques have been developed to increase light production including the use of other explosives, external flashes, image intensifiers, and flash coatings. Of these techniques, flash coatings are the simplest to field, relatively cheap, and have been widely adopted. The technique only consists of materials being applied to the surface of the explosive/imaging plane. Despite this, minimal information is openly available on contrasting coating materials and characteristics, which has led to many different materials being used including cigarette paper, fine sand, alumina (Al2O3), and magnesium oxide (MgO). Here, this work investigated alumina as a flash coating and characterized the effects of coating thickness and particle size on light production. It was found that particles below 45 µm produce the best results with uniform light, and a minimum thickness of 7 µm of the flash coating was needed for distinguishing between the leading shock and product gases. To isolate the influence of the high explosives (HE) only PBX 9501 was used. Simulations using the hydrodynamic code CTH, by Sandia National Labs, were performed to model the flash coatings and supply further insight. [ABSTRACT FROM AUTHOR]

Published
2023
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50. The influence of microstructure and polymorphic conformer on the shock sensitivity of 1,3,5,7-tetranitro-1,3,5,7-tetrazoctane (HMX).

Author

Cummock, Nicholas R., Lawrence, Joseph R., Blum-Sorensen, Christian J., Vuppuluri, Vasant S., and Son, Steven F.

Subjects
PHASE transitions, PARTICLE size distribution, CRYSTAL lattices, MICROSTRUCTURE
Abstract

The influence on 1,3,5,7-tetranitro-1,3,5,7-tetrazoctane (HMX) shock sensitivity resulting from damage due to phase transition versus that of the polymorphic conformer and crystal lattice change in heated HMX are explored in this work. Samples of class III HMX at 1.24 g/cm3 are shocked in a modified gap test, which yields quantitative, rather than 'go/no-go,' results. Microstructural characterization of similarly prepared samples is used to draw conclusions about the primary driver of the difference in sensitivity between pristine β -HMX, thermally induced δ -HMX, and HMX that has spontaneously reverted from δ → β -HMX. It is found, surprisingly, that large crystals of HMX incur a slight decrease in shock sensitivity after undergoing δ -phase transition and/or spontaneous reversion from δ → β -HMX. The difference between shock sensitivity results of a significantly smaller HMX particle size distribution are inconclusive using this test configuration. Further testing of the small particle size distribution using a different experimental design that allows lower input pressures may be more useful for comparison. The results of this study indicate that while the increased crack cross-sectional area in HMX crystals drives an increase in impact sensitivity, it drives a decrease in sensitivity in the shock regime for the conditions studied. [ABSTRACT FROM AUTHOR]

Published
2023
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