Prediction of Probabilistic Shock Initiation Thresholds of Energetic Materials through Evolution of Thermal-mechanical Dissipation and Reactive Heating

Abstract The ignition threshold of an energetic material (EM) quantifies the macroscopic conditions for the onset of self-sustaining chemical reactions. The threshold is an important theoretical and practical measure of material attributes that relate to safety and reliability. Historically, the thresholds are measured experimentally. Here, we present a new Lagrangian computational framework for establishing the probabilistic ignition thresholds of heterogeneous EM out of the evolutions of coupled mechanical-thermal-chemical processes using mesoscale simulations. The simulations explicitly account for microstructural heterogeneities, constituent properties, and interfacial processes and capture processes responsible for the development of material damage and the formation of hotspots in which chemical reactions initiate. The specific mechanisms tracked include viscoelasticity, viscoplasticity, fracture, post-fracture contact, frictional heating, heat conduction, reactive chemical heating, gaseous product generation, and convective heat transfer. To determine the ignition threshold, the minimum macroscopic loading required to achieve self-sustaining chemical reactions with rate of reactive heat generation exceeding the rate of heat loss due to conduction and other dissipative mechanisms is determined. Probabilistic quantification of the processes and the thresholds are obtained via the use of statistically equivalent microstructure samples sets (SEMSS). The predictions are in agreement with available experimental data.

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Achieving tunable chemical reactivity through photo-initiation of energetic materials at metal oxide surfaces

Physical Chemistry Chemical Physics ◽

10.1039/d0cp04069j ◽

2020 ◽

Vol 22 (43) ◽

pp. 25284-25296

Author(s):

Maija M. Kuklja ◽

Roman Tsyshevsky ◽

Anton S. Zverev ◽

Anatoly Mitrofanov ◽

Natalya Ilyakova ◽

...

Keyword(s):

Metal Oxide ◽

Chemical Reactions ◽

Energetic Materials ◽

Chemical Reactivity ◽

Energetic Material ◽

Oxide Surfaces ◽

Oxide Interfaces ◽

Metal Oxide Surfaces

Photo-stimulated chemical reactions in energetic materials can be highly controlled by selectively designing energetic material – metal oxide interfaces with tailored properties.

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Introduction of the acylamino group to bridged bis(nitroamino-1,2,4-triazole): a strategy for tuning the sensitivity of energetic materials

New Journal of Chemistry ◽

10.1039/d1nj03551g ◽

2021 ◽

Vol 45 (38) ◽

pp. 18059-18064

Author(s):

Dongxu Chen ◽

Jiangshan Zhao ◽

Hongwei Yang ◽

Hao Gu ◽

Guangbin Cheng

Keyword(s):

Energetic Materials ◽

Energetic Material

Introduction of the acylamino group into energetic material compounds will contribute to balancing the sensitivity and the energy.

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Shock-Induced Chemical Reactions in Multi-Functional Structural Energetic Intermetallic Nanocomposite Mixtures

Aerospace ◽

10.1115/imece2005-81636 ◽

2005 ◽

Author(s):

V. Narayanan ◽

X. Lu ◽

S. Hanagud

Keyword(s):

Metal Oxides ◽

Chemical Reactions ◽

Energetic Materials ◽

Thermal Loading ◽

Volume Fraction ◽

Irreversible Thermodynamics ◽

Irreversible Processes ◽

Finite Difference Schemes ◽

Dual Functional ◽

Metal Metal

Shock induced chemical reactions of intermetallics or mixtures of metal and metal-oxides are also used to synthesize new materials with unique phases and microstructures. These materials are also of significant interest to the energetics community because of the significant amount of heat energy released during chemical reactions when subjected to shock and/or thermal loading. Binary energetic materials are classified into two categories— metal/metal oxides and intermetallics. When these materials are synthesized at a nano level with binders and other structural reinforcements, the strength of the resulting mixture increases. Thus, these materials can be used as dual-functional binary energetic structural materials. In this paper, we study the shock-induced chemical reactions of intermetallic mixtures of nickel and aluminum of varying volume fractions of the constituents. The chemical reaction between nickel and aluminum produces different products based on the volume fraction of the starting nickel and aluminum. These chemical reactions along with the transition state are modeled at the continuum level. In this paper, the intermetallic mixture is impact loaded and the subsequent shock process and associated irreversible processes such as void collapse and chemical reactions are modeled in the framework of non-equilibrium thermodynamics. Extended irreversible thermodynamics (EIT) is used to describe the fluxes in this system and account for the associated irreversible processes. Numerical simulations of the intermetallic mixture are carried out using finite difference schemes.

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A Coupled Computational Framework for the Transient Heat Transfer in a Circular Pipe Heated Internally With Expanding Heat Sources

Journal of Pressure Vessel Technology ◽

10.1115/1.4047711 ◽

2020 ◽

Vol 142 (6) ◽

Author(s):

Chaobin Hu ◽

Xiaobing Zhang

Keyword(s):

Heat Transfer ◽

Heat Exchange ◽

Energetic Materials ◽

Transfer Problem ◽

Lumped Parameter Model ◽

Heat Transfer Problem ◽

Transient Heat Transfer ◽

Combustion Model ◽

Heat Sources ◽

Computational Framework

Abstract In the present work, a transient heat transfer problem induced by internal combustion of energetic materials was studied. Most of previous studies utilized a lumped-parameter model to predict the parameter distributions of the hot combustion products, which determine the boundary conditions for the transient heat transfer problem. Moreover, the heat exchange between the solids and the fluids was ignored in the combustion model. In order to improve the modeling accuracy, a one-dimensional (1D) two-phase flow model was utilized to predict the fluid fields and the heat exchange was coupled into the combustion model. Based on the commercial software abaqus, the transient heat transfer in the combustion chamber was studied using a finite element method. The meshes near the inner surface were refined to capture the high temperature gradients along the radial direction of the barrel. Results indicate that the coupled model is capable of solving the transient heat transfer problems heated by distributed moving heat sources. The coupled computational framework provides foundations for the study of local wear and erosion of solids in extreme working conditions.

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Solidification Heat Transfer and Base Separation Analysis in the Casting of an Energetic Material in a Projectile

Heat Transfer, Part B ◽

10.1115/imece2005-80432 ◽

2005 ◽

Cited By ~ 3

Author(s):

Dawei Sun ◽

S. Ravi Annapragada ◽

Suresh V. Garimella ◽

Sanjeev Sing

Keyword(s):

Heat Transfer ◽

Finite Element ◽

Numerical Model ◽

Residual Stresses ◽

Energetic Materials ◽

Energetic Material ◽

Complex Geometries ◽

Experimental Measurements ◽

Linear Temperature ◽

High Prandtl Number

This paper investigates the problem of base separation in the casting of energetic materials in a projectile. Special challenges that arise in casting high Prandtl number energetic materials in projectiles of complex geometries are addressed. A comprehensive numerical model is developed by integrating finite volume and finite element methods to analyze the thermal and flow fields as well as the residual stresses. The predictions, which are confirmed by experimental measurements, suggest that sustenance of a linear temperature profile along the projectile axis can eliminate base separation, and also reduce residual stresses in the final casting.

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Laser Diagnostics Of Nascent Gaseous Product Species Formed In Chemical Reactions On Surfaces

10.1117/12.951612 ◽

1989 ◽

Cited By ~ 1

Author(s):

David S. Hsu

Keyword(s):

Chemical Reactions ◽

Laser Diagnostics ◽

Gaseous Product ◽

Product Species

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Nanostructured Energetic Materials with Sol-gel Methods

MRS Proceedings ◽

10.1557/proc-800-aa2.2 ◽

2003 ◽

Vol 800 ◽

Cited By ~ 15

Author(s):

Alexander E. Gash ◽

Joe H. Satcher ◽

Randall L. Simpson ◽

Brady J. Clapsaddle

Keyword(s):

Thermal Properties ◽

Energetic Materials ◽

Energetic Material ◽

Sol Gel ◽

Small Scale ◽

Fine Grained ◽

Electron Microscopies ◽

Burn Rate ◽

Scanning Electron

AbstractThe utilization of sol-gel chemical methodology to prepare nanostructured energetic materials as well as the concepts of nanoenergetics is described. The preparation and characterization of two totally different compositions is detailed. In one example, nanostructured aerogel and xerogel composites of sol-gel iron (III) oxide and ultra fine grained aluminum (UFG Al) are prepared, characterized, and compared to a conventional micron-sized Fe2O3/Al thermite. The exquisite degree of mixing and intimate nanostructuring of this material is illustrated using transmission and scanning electron microscopies (TEM and SEM). The nanocomposite material has markedly different energy release (burn rate) and thermal properties compared to the conventional composite, results of which will be discussed. Small-scale safety characterization was performed on the nanostructured thermite. The second nanostructured energetic material consists of a nanostructured hydrocarbon resin fuel network with fine ammonium perchlorate (NH4ClO4) oxidizer present.

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Chemical Reactions and Other Behaviors of High Energetic Materials under Static Ultrahigh Pressures

Materials Science Forum ◽

10.4028/www.scientific.net/msf.465-466.189 ◽

2004 ◽

Vol 465-466 ◽

pp. 189-194 ◽

Cited By ~ 3

Author(s):

Naoyuki Goto ◽

Hiroshi Yamawaki ◽

Kenichi Tonokura ◽

Kunihiko Wakabayashi ◽

Masatake Yoshida ◽

...

Keyword(s):

Chemical Reactions ◽

Energetic Materials

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Kinetic Compensation Effect of Kinetic Parameters of Thermal Explosion Test

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.184-185.1408 ◽

2012 ◽

Vol 184-185 ◽

pp. 1408-1417

Author(s):

Ying Hui Shao ◽

Zi Ru Liu ◽

Xiao Ning Ren ◽

Shu Yun Heng ◽

Pu Yue ◽

...

Keyword(s):

Kinetic Parameters ◽

Thermal Explosion ◽

Energetic Materials ◽

Compensation Effect ◽

Energetic Material ◽

Regression Equation ◽

Kinetic Temperature ◽

Single Compound ◽

Main Component ◽

Explosion Test

The kinetic parameters of thermal explosion tests with five-second delay for 273 energetic materials were analyzed. The compensation effect exists between the two thermal explosion kinetic parameters of these energetic materials, e.g. lnA and Eb. The kinetic parameters of these energetic materials can be expressed by a single linear regression equation for the single compound or mixture under all conditions. The slopes of the regression equation for various systems are in the range from 0.1952 to 0.2413 (mol•kJ-1). The regression equation for single compound or mixture with one type of energetic material as main component has better linearity. Therefore, their “iso-kinetic temperature” Tik is close to their thermal explosion temperature Tb and the “iso-kinetic delay period”τik is also close to the 5 seconds.

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Molecular Composition, Structure, and Sensitivity of Explosives

MRS Proceedings ◽

10.1557/proc-296-25 ◽

1992 ◽

Vol 296 ◽

Cited By ~ 2

Author(s):

Carlyle B. Storm ◽

James R. Travis

Keyword(s):

Molecular Structure ◽

Hot Spots ◽

Energetic Materials ◽

Physical State ◽

Hot Spot ◽

Energetic Material ◽

Specific Situation ◽

Reaction Products ◽

Ambient Conditions ◽

Delayed Reaction

AbstractHigh explosives, blasting agents, propellants, and pyrotechnics are all metastable relative to reaction products and are termed energetic materials. They are thermodynamically unstable but the kinetics of decomposition at ambient conditions are sufficiently slow that they can be handled safely under controlled conditions. The ease with which an energetic material can be caused to undergo a violent reaction or detonation is called its sensitivity. Sensitivity tests for energetic materials are aimed at defining the response of the material to a specific situation, usually prompt shock initiation or a delayed reaction in an accident. The observed response is always due to a combination of the physical state and the molecular structure of the material. Modeling of any initiation process must consider both factors. The physical state of the material determines how and where the energy is deposited in the material. The molecular structure in the solid state determines the mechanism of decomposition of the material and the rate of energy release. Slower inherent reaction chemistry leads to longer reaction zones in detonation and inherently safer materials. Slower chemistry also requires hot spots involved in initiation to be hotter and to survive for longer periods of time. High thermal conductivity also leads to quenching of small hot spots and makes a material more difficult to initiate. Early endothermic decomposition chemistry also delays initiation by delaying heat release to support hot spot growth. The growth to violent reaction or detonation also depends on the nature of the early reaction products. If chemical intermediates are produced that drive further accelerating autocatalytic decomposition the initiation will grow rapidly to a violent reaction.

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