| IDS001 |
Quantitative Distinction between Detonation and Afterburn Energy Deposition Using Pressure-Time Histories in Enclosed Explosions |
Ames, Richard |
NSWC, Dahlgren Division |
US |
| IDS002 |
Numerical and Theoretical Investigations on Detonation Confinement Sandwich Tests |
Aslam, Tariq |
LANL |
US |
| IDS003 |
ISENTROPIC COMPRESSION STUDIES OF THE MESOSCALE RESPONSE OF ENERGETIC COMPOSITES AND CONSTITUENTS |
Baer, Mel |
SNL |
US |
| IDS004 |
GENERALIZED THERMODYNAMIC EQUATION OF STATE FOR REACTING ALUMINIZED EXPLOSIVES |
Baker, Ernest |
ARDEC |
US |
| IDS005 |
Simulation of Detonation Propagation and Failure in Granular Explosive Charges |
Banton, Rohan |
ARL |
US |
| IDS006 |
Coupling Grain Scale and Bulk Mechanical Response for PBXs using Numerical Simulations of Real Microstructures |
Bardenhagen, Scott |
LANL |
US |
| IDS007 |
Cook-off Model Development and Analysis of Energetic Materials using Sandia Instrumented Thermal Ignition (SITI) Experimental Data |
Barra, Amanda |
SNL |
US |
| IDS008 |
Equation of state for high explosives detonation products with explicit polar and ionic species |
Bastea, Sorin |
LLNL |
US |
| IDS009 |
Higher-Order DSD for Detonation Propagation: DSD for Detonation Driven by Multi-Step Chemistry Models with Disparate Rates |
Bdzil, John |
LANL |
US |
| IDS011 |
Mechanical Response and Shear Initiation of Double-Base Propellants |
Bilyk, Stephan |
ARL |
US |
| IDS012 |
Electrostatic Discharge Sensitivity of Pressed Solid High Explosives |
Borovina, Dan |
LANL |
US |
| IDS013 |
LASER-INDUCED DECOMPOSITION OF ENERGETIC MATERIALS AT STATIC HIGH PRESSURES: STUDY OF THE HNO3 / 2 – NITROPROPANE MIXTURE |
Bouyer, Viviane |
CEA |
FR |
| IDS014 |
The Initiation of Fine Particle Hexanitrostilbene Using Laser-Driven Flyer Plates |
Bowden, Mike |
AWE |
UK |
| IDS015 |
Approaches to the simulation of steady highly non-ideal detonations in heterogeneous explosives |
Braithwaite, Martin |
Cranfield University |
UK |
| IDS016 |
A THEORETICAL STUDY OF THE DEPENDENCE OF NON IDEAL DETONATION AND THE DIAMETER EFFECT ON THE DECOMPOSITION RATES IN CYLINDRICAL CHARGES OF POLYTROPIC EXPLOSIVE |
Braithwaite, Martin |
Cranfield University |
UK |
| IDS018 |
CAN THERMAL ANALYSIS RELIABLY PREDICT THERMAL COOKOFF BEHAVIOR? |
Burnham, Alan K. |
LLNL |
US |
| IDS019 |
Atmospheric Effects on Time-Resolved Emission Measurements of Detonation and Combustion Products |
Carney, Joel |
NSWC |
US |
| IDS020 |
Effect of Particle Size and Crystal Quality on the Critical Shock Initiation Pressures of RDX/HTPB Formulations |
Caulder, Stanley |
NSWC |
US |
| IDS021 |
Prediction of Confinement Effects on Detonation With an Analytical Two-dimensional Non-ideal Detonation Model |
Chan, Sek |
Orica CA |
CA |
| IDS022 |
Influence of Nanoparticles in Energetic Compositions |
Collet, C. |
SNPE |
FR |
| IDS023 |
An investigation into the mechanisms responsible for delayed detonations in projectile impact experiments |
Cook, Malcolm |
QinetiQ Ltd |
UK |
| IDS024 |
Parameterisation of the CHARM Reactive Flow Model Using Kinetic Parameters Derived from Cook-Off Experiments |
Cook, Malcolm |
QinetiQ Ltd |
UK |
| IDS025 |
Methods For Evaluating Aluminized RDX Explosives |
Cooper, Marcia |
SNL |
US |
| IDS026 |
Experimental validation of an analytical model for prediction of shock to detonation transition resulting from high velocity impacts |
Curtis, John |
QinetiQ Ltd |
UK |
| IDS027 |
The relationship between particle morphology and sensitivity for pure granular RDX |
Czerski, Helen |
Cavendish Laboratory, University of Cambridge |
UK |
| IDS028 |
Solid-state phase change in HMX during dropweight impact |
Czerski, Helen |
University of Cambridge |
UK |
| IDS029 |
Modeling the Bulk Mechanical Response of Heterogeneous Explosives Based on Microstructural Information |
De, Suvranu |
Rensselaer Polytechnic Institute |
US |
| IDS030 |
Development of Warheads Venting Technology for Cook-off Response Mitigation |
DeFisher, Stanley |
ARDEC |
US |
| IDS032 |
Detonation in Metal–Teflon Mechanoactivated Composites |
Dolgoborodov, Alexander |
ICP RAS |
RU |
| IDS033 |
Detonation-like Processes in Teflon/Al-based Explosive Mixtures |
Dolgoborodov, Alexander |
ICP RAS |
RU |
| IDS035 |
Application of Various Global Decomposition Model Forms to Energetic Material Cookoff |
Erikson, William |
SNL |
US |
| IDS036 |
REACTION ZONES AND CONDUCTIVE ZONES IN DENSE EXPLOSIVES |
Ershov, Alexander |
Lavrentyev Institute of Hydrodynamics SB RAS |
RU |
| IDS038 |
Examination of high-reaction velocity thermite propagation |
Foley, Timothy |
LANL |
US |
| IDS039 |
Behavior of Explosives Under Pressure in a Diamond Anvil Cell |
Foltz, Mary |
LLNL |
US |
| IDS040 |
Non-molecular phases in high explosive detonation |
Fried, Laurence |
LLNL |
US |
| IDS041 |
Effect of Scale on the Blast Wave from a Metalized Explosive |
Frost, David |
McGill University |
CA |
| IDS042 |
A combined discrete/finite element method applied to energetic materials at the meso-scale simulation under shock loading |
Fu, Hua |
China Academy of Engineering Physics |
CN |
| IDS043 |
Three-Dimensional Ignition and Growth Reactive Flow Modeling of Prism Failure Tests on PBX 9502 |
Garcia, Mark |
LLNL |
US |
| IDS044 |
Improved Wood-Kirkwood Detonation Chemical Kinetics |
Glaesemann, Kurt |
LLNL |
US |
| IDS045 |
On Detonation of Aluminized BTNEN-containing Mixtures |
Gogulya, Michael |
ICP RAS |
RU |
| IDS046 |
Generalized Steady-State Model of Heterogeneous Detonation with Non-Uniform Particles Heating |
Gonor, Alexander |
University of Toronto |
CA |
| IDS047 |
Theory and Analysis of Non-Ideal Detonation for RDX/Dilute Metal Mixtures |
Gonthier, Keith |
Louisiana State University |
US |
| IDS048 |
High pressure phase of RDX |
Goto, Naoyuki |
The University of Tokyo |
JP |
| IDS049 |
Small-Scale Shock Reactivity and Internal Blast |
Granholm, Richard |
NSWC |
US |
| IDS050 |
Shock-Induced Electro Conductivity of the Insensitive High Explosive. |
Grebenkin, Konstantin |
VNIITF |
RU |
| IDS051 |
Detonation Pressure Measurements on PETN |
Green, Leroy |
LLNL |
US |
| IDS052 |
Thermal Ignition of Explosives Using Pyrotechnics and Hypergolics |
Guirguis, Raafat |
NSWC |
US |
| IDS053 |
Phase Diagram of Epsilon CL-20 at High-Pressure and Temperature |
Gump, Jared |
NSWC |
US |
| IDS054 |
Shock initiation of the TATB based explosive PBX 9502 cooled to -55 degrees Celcius |
Gustavsen, R. L. |
LANL |
US |
| IDS055 |
Photographic Observation of Low Velocity Detonation in Nitromethane |
Hamashima, Hideki |
Kumamoto University |
JP |
| IDS056 |
Development of a reactive burn model: Effects of particle contact distribution |
Hamate, Yuichiro |
REEF, University of Florida |
US |
| IDS057 |
The CREST Reactive-Burn Model |
Handley, Caroline |
AWE |
UK |
| IDS058 |
Application of the Embedded Fiber Optic probe to make continuous measurements of detonation speed in high explosive detonation studies |
Hare, D. E. (Dave) |
LLNL |
US |
| IDS059 |
Detonation Behavior of Adjacent High Explosive Charges with Different Detoantion Velocities |
Held, Prof. Dr. Manfred |
TDW |
DE |
| IDS060 |
WENO5M Shock-fitted Solutions to 2-Dimensional Euler Equations with Reaction |
Henrick, Andrew |
LANL |
US |
| IDS061 |
AN IGNITION LAW FOR PBX 9501 FROM THERMAL EXPLOSION TO DETONATION |
Henson, Bryan |
LANL |
US |
| IDS062 |
Comparison of the Detonation Failure Mechanism in Homogeneous and Heterogeneous Explosives |
Higgins, Andrew |
McGill University |
CA |
| IDS063 |
PBX 9502 Detonation Shock Dynamics Calibration: Repeatablity and Dependence on Material Lot |
Hill, Larry |
LANL |
US |
| IDS065 |
Pressure-Induced Molecular Structural change on Aromatic Nitro Compounds |
Hiyoshi, Reiko |
National Research Institute of Police Science, JAPAN |
JP |
| IDS066 |
Modeling HMX Ignition using an Enthalpy Formulation |
Hobbs, Michael |
SNL |
US |
| IDS067 |
INITIATION MECHANISMS IN SINGLE CRYSTAL EXPLOSIVES: DISLOCATIONS, ELASTIC LIMITS, AND INITIATION THRESHOLDS |
Hooks, Daniel |
LANL |
US |
| IDS068 |
Modeling Hemispheric Detonation Experiments in 2 and 3 Dimensions |
Howard, W. Michael |
LLNL |
US |
| IDS069 |
ALE3D Simulations of Gap Closure and Surface Ignition for Cookoff Modeling |
Howard, W. Michael |
LLNL |
US |
| IDS070 |
Characterization of Damaged Materials |
Hsu, Peter |
LLNL |
US |
| IDS071 |
Experimental Study on Deflagration to Detonation Transition of NEPE Solid Propellants |
Huang, Fenglei |
Beijing Institute of Technology |
CN |
| IDS072 |
Runaway Reaction in a Solid Explosive Containing a Single Crack |
Jackson, Scott |
LANL |
US |
| IDS073 |
Links between Macroscopic Behaviour and Explosive Morphology in Shock to Detonation Transitions |
James, Hugh |
AWE |
UK |
| IDS074 |
An Investigation of the Detonation Characteristics of Some Non-Ideal Explosive Compositions Based Upon Ammonium Nitrate. |
James, Hugh |
AWE |
UK |
| IDS075 |
Large-scale Molecular Dynamics studies of quasi-static and shock compression in crystalline ß-HMX |
Jaramillo, Eugenio |
LANL |
US |
| IDS076 |
Low Velocity Impacts on Explosive Assemblies |
Jones, Andrew |
AWE |
UK |
| IDS077 |
MEASUREMENT OF IGNITION THRESHOLD OF EXPLOSIVES USING A HYBRID HOPKINSON BAR-DROP WEIGHT TEST |
Joshi, Vasant |
NSWC |
US |
| IDS078 |
NEW TECHNIQUES IN CHARACTERIZATION OF HIGH STRAIN-RATE BEHAVIOR OF EXPLOSIVES |
Joshi, Vasant |
NSWC |
US |
| IDS080 |
Detonation Diffraction, Dead Zones, and the Ignition-and-Growth Model |
Kapila, Ashwani |
Rensselaer Polytechnic Institute |
US |
| IDS081 |
Overdriven Detonation in High Density Explosives Containing Tungsten Powder |
Kato, Hisaatsu |
1Nippon Koki Co., Ltd. |
JP |
| IDS082 |
Detonation Characteristics of Packed Beds of Aluminum Saturated with Nitromethane |
Kato, Yukio |
Nippon koki Co.,Ltd. |
JP |
| IDS083 |
Floret Test Observations on Detonation Spreading in Insensitive Explosives |
Kennedy, James |
Hazards & Explosives Research & Education, LLC |
US |
| IDS084 |
On the Nature of Variations in Density and Composition within TATB-based Plastic Bonded Explosives |
Kinney, John H. |
LLNL |
US |
| IDS085 |
Laminar and deconsolidative deflagration of RDX-based explosives at high pressures |
Koerner, Jake |
LLNL |
US |
| IDS086 |
Non-Classical Steady-State Detonation Regimes in TNETB |
Kolesnikov, Sergei |
Institute of Problems of Chemical Physics RAS |
RU |
| IDS087 |
Observation and numerical simulation of high explosive under shock loading |
Kubota, Shiro |
National Institute of Advanced Industrial Science and Technology |
JP |
| IDS088 |
Numerical study on the scale effect in gap test of emulsion explosive |
Kubota, Shiro |
National Institute of Advanced Industrial Science and Technology |
JP |
| IDS089 |
The Hydrodynamics of the Early Stages of the Shock to Detonation Transition |
Lambourn, Brian |
AWE |
UK |
| IDS090 |
Stochastic Simulation : an Alternative Approach to Model Complex Chemical Reactions |
Lapebie, Emmanuel |
French MOD/DGA/DET/CEG |
FR |
| IDS091 |
Secondary Effects on Projectile-Impact Shock Initiation |
Lawrence, William |
ARL |
US |
| IDS092 |
Combined Initial Air Blast and Quasi-Static Overpressure Assessment of Pressed Aluminized Explosives |
Lee, Richard |
NSWC |
US |
| IDS093 |
SHOCK DESENSITIZATION EFFECT IN THE STANAG 4363 CONFINED EXPLOSIVE COMPONENT WATER GAP TEST (ECWGT) FOR COMPONENTS HAVING A DIAMETER LESS THAN 5 MM |
Lefrancois, Alexandre |
LLNL |
US |
| IDS094 |
Simulation of Sympathetic Reaction Tests for PBXN-109 |
Lu, Jing Ping |
Weapons Systems Division, Defence Science and Technology Organisation |
AU |
| IDS095 |
CHARGE LENGTH EFFECT ON DETONATION PARAMETERS OF THE TATB-BASED INSENSITIVE HIGH EXPLOSIVE |
Lubyatinsky, Sergey |
Russian Federal Nuclear Center – Institute of Technical Physics |
RU |
| IDS096 |
Rapid Data Analysis Methodologies for Streak Camera Images: Measurement of Detonation Velocity and DDT Distance of Lead Azide at Sub-Millimeter Diameters |
Madden, Sean |
SNL |
US |
| IDS097 |
Thermal Explosion Violence For Several Explosives – Measurements and Interpretation |
Maienschein, Jon |
LLNL |
US |
| IDS098 |
Evaluation of the Acceleration Ability of Aluminized High Explosives |
Makhov, Michael |
Semenov Institute of Chemical Physics RAS |
RU |
| IDS099 |
Measurement and ALE3D Simulation of Violence in a Slow Cookoff Experiment with LX-10 and AerMet 100 Steel |
McClelland, Matthew |
LLNL |
US |
| IDS100 |
ALE3D Simulation of Heating and Violence in a Fast Cookoff experiment with LX-10 |
McClelland, Matthew |
LLNL |
US |
| IDS101 |
An Experimental Investigation of Detonation Corner Turning using High Resolution Radiography |
Molitoris, John |
LLNL |
US |
| IDS103 |
A Model for Thermal Cookoff and Detonation of High Explosives |
Nichols, Albert |
LLNL |
US |
| IDS104 |
Energetic Materials at High Compression: First-Principles Density Functional Theory Studies |
Oleynik, Ivan |
University of South Florida |
US |
| IDS105 |
N-Guanylurea-Dinitramide (FOX-12): A New Extremely Insensitive Energetic Material for Explosives Applications |
Ostmark, Henric |
Swedish Defence Research Agency, FOI |
SE |
| IDS107 |
Evaluation of Aluminum Participation in the Development of Reactive Waves in Shock-Compressed HMX |
Pahl, Robert |
SNL |
US |
| IDS108 |
Closed-Bomb Combustion of Hot, Thermally Damaged PBX 9501 |
Parker, Gary |
LANL |
US |
| IDS109 |
Modeling Initiation by a Reflected Shock |
Partom, Yehuda |
Rafael |
IL |
| IDS110 |
Factors affecting quantitative high-explosive reaction violence measurements |
Perry, William Lee |
LANL |
US |
| IDS111 |
Matrix Isolation Spectroscopy Applied on RDX Reaction Products |
Pettersson, Anna |
Swedish Defence Research Agency, FOI |
SE |
| IDS112 |
Formation of CRZ 3D structure at SDT and at Shear Initiation of PBX: Effects of Front Irradiation and Reaction localization in HMX crystals |
Plaksin, Igor |
LEDAP - Lab. of Energetics and Detonics |
PT |
| IDS113 |
CONSTITUTIVE MODEL AND EQUATION OF STATE OF UNREACTED PBXN-109 |
Quidot, M. |
SNPE |
FR |
| IDS114 |
The stress vs. strain response of single HMX crystals |
Rae, Philip |
LANL |
US |
| IDS115 |
Multi-scale Computer Simulations to Study the Reaction Zone of Solid Explosives |
Reaugh, John |
LLNL |
US |
| IDS116 |
Detonation Interaction with Metal Particles in Explosives |
Ripley, Robert |
Martec Ltd. |
CA |
| IDS117 |
Evaluation of the Mechanical and Thermal Derivatives of the CJ State with an application to Nitromethane |
Roth, Julius |
Retired |
US |
| IDS118 |
The Dynamics of Detonation Failure in Conical PBX 9502 Charges |
Salyer, Terry |
LANL |
US |
| IDS119 |
Explosive-Driven Shock Waves in Argon |
Salyer, Terry |
LANL |
US |
| IDS120 |
Deflagration-to-Detonation Transition in LX-04 as a Function of Loading Density, Temperature, and Confinement |
Sandusky, Harold |
NSWC |
US |
| IDS121 |
Thermal and Mechanical damage of PBX’s, Part II |
Scholtes, Gert |
TNO |
NL |
| IDS122 |
Atomistic simulations of quasi-static and shock loading of HMX crystals |
Sewell, Tommy |
LANL |
US |
| IDS123 |
A Preliminary ab initio Detonation Products Equation of State Including Quantum Configurational Energies and Efficient Monte Carlo Sampling |
Shaw, M. Sam |
LANL |
US |
| IDS124 |
Homogeneous shock initiation in neat and chemically sensitized nitromethane |
Sheffield, Stephen A. |
LANL |
US |
| IDS125 |
Hydrodynamic Stability Properties of Condensed-Phase Detonations With Common Engineering-Scale High-Explosive Models |
Short, Mark |
University of Illinois at Urbana-Champaign |
US |
| IDS126 |
ABOUT DEPENDENCE OF DETONATION VELOCITY ON DENSITY FOR EMULSION EXPLOSIVES |
Silvestrov, Victor |
Lavrentyev Institute of Hydrodynamics SB RAS |
RU |
| IDS127 |
THE EVOLUTION OF A THERMAL EXPLOSION- SPATIAL AND TEMPERATURE PROFILES INTERNAL TO A PBX9501 THERMAL EXPLOSION |
Smilowitz, Laura |
LANL |
US |
| IDS128 |
Molecular dynamics modelling of shock and detonation fenomena in liquids of polyatomic molecules. |
Smirnov, Andrei |
Institute of Problem of Chemical Physics of Russian Academy of Sciences |
RU |
| IDS129 |
Detonation properties analysis of homogeneous explosives by molecular dynamics. |
Soulard, Laurent |
CEA |
FR |
| IDS130 |
The Performance of Explosive Shock-Initiation Models under Complex Shock Loading |
Starkenberg, John |
ARL |
US |
| IDS131 |
A multiphase model for heterogenous explosives in both the dense and dilute limits |
Stevens, David |
LLNL |
US |
| IDS132 |
The Initiation Mechanism of Direct Optical Initiation (DOI) Detonators |
Stewart, Scott |
University of Urbana-Champaign |
US |
| IDS133 |
Determination of the Lighting Radius for Application of Detonation Shock Dynamics Consistent with Ignition Transients in Condensed Explosives |
Stewart, Scott |
University of Illinois at Urbana-Champaign |
US |
| IDS134 |
Modeling detonation diffraction and dead zones in PBX-9502 |
Stewart, Scott |
University of Illinois at Urbana-Champaign |
US |
| IDS135 |
Deflagration Kinetics of Energetic Binder, PGN |
Stoltz, Chad |
NSWC |
US |
| IDS136 |
The Modeling of the Shock Reactivity and Detonation Property Trends of Explosives with Different Particle Size Distributions |
Sutherland, Gerrit |
NSWC |
US |
| IDS138 |
Microenergetic Research Involving a Coupled Experimental and Computational Approach to Evaluate Microstructural Effects on Detonation and Combustion at Sub-Millimeter Geometries |
Tappan, Alexander S. |
SNL |
US |
| IDS139 |
Shock Initiation of the PETN-based Explosive LX-16 |
Tarver, Craig |
LLNL |
US |
| IDS142 |
Reactive gas phase compression due to shock-induced cavity collapse in energetic materials |
Tran, Linhbao |
ARL |
US |
| IDS143 |
Shock-Induced Reaction in Nitromethane-Impregnated Geometrically-Regular Sample Configurations |
Trott, Wayne |
SNL |
US |
| IDS144 |
REACTION ZONE STRUCTURE FOR PRESSED HE AND MIXTURES OF HIGH EXPLOSIVES WITH ADDITIONS |
Utkin, Alexander |
Institute of Problems of Chemical Physics RAS |
RU |
| IDS145 |
LOW AMPLITUDE SINGLE AND MULTIPLE SHOCK INITIATION EXPERIMENTS AND MODELING OF LX-04 |
Vandersall, Kevin |
LLNL |
US |
| IDS146 |
THRESHOLD STUDIES ON TNT, COMPOSITION B, C-4, and ANFO EXPLOSIVES USING THE STEVEN IMPACT TEST |
Vandersall, Kevin |
LLNL |
US |
| IDS147 |
SHOCK INITIATION EXPERIMENTS AND MODELING OF COMPOSITION B, C-4, and ANFO |
Vandersall, Kevin |
LLNL |
US |
| IDS148 |
A NEW ACCURATE EQUATION OF STATE FOR FLUID DETONATION PRODUCTS BASED ON AN IMPROVED VERSION OF THE KLRR PERTURBATION THEORY |
Victorov, Sergey |
Moscow Engineering Physics Institute (State University) |
RU |
| IDS149 |
AN APPROACH FOR GENERATING A COMPUTATIONALLY EFFICIENT EQUATION OF STATE FOR CONDENSED EXPLOSIVES WHOSE DETONATION PRODUCTS UNDERGO PHASE TRANSITIONS |
Victorov, Sergey |
Moscow Engineering Physics Institute (State University) |
RU |
| IDS150 |
Kinetic Modeling of Slow Energy Release in Non-Ideal Carbon Rich Explosives |
Vitello, Peter |
LLNL |
US |
| IDS151 |
Novel High Energetic Materials: Calculation and Synthesis Attempts of Metal Pentazolates |
Wallin, Sara |
Swedish Defence Research Agency, FOI |
SE |
| IDS152 |
Microstructure Effects on Detonation Performance of HNS and CL-20 |
Welle, Eric |
SNL |
US |
| IDS153 |
Some Issues Regarding the Hydrocode Implementation of the CREST Reactive Burn Model |
Whitworth, Nicholas |
AWE |
UK |
| IDS154 |
THE EFFECT OF ELECTRICAL ENERGY ON DETONATION FAILURE IN WEDGES OF THE TATB-BASED EXPLOSIVE EDC35 |
Winter, Ron |
AWE |
UK |
| IDS156 |
On the Response of an IHE to long duration low amplitude shocks |
Wortley, Steve |
AWE |
UK |
| IDS157 |
The effect of binder concentration on IHE booster compositions |
Wortley, Steve |
AWE |
UK |
| IDS158 |
Recent Advances in Thermal Explosion Modeling of HMX-based Explosives |
Yoh, Jack |
Seoul National University |
KR |
| IDS159 |
New allotropes of single-bonded nitrogen by first-principle computational experiments on one-dimensional helical structures |
Zahariev, Federico |
University of Ottawa |
CA |
| IDS160 |
Composition B Decomposition and Ignition Model |
Zerkle, David |
LANL |
US |
| IDS161 |
Casing Influence on Ignition and Combustion of Aluminum Particles in Cylindrical Explosive Charges |
Zhang, Fan |
Defence Research and Development CA - Suffield |
CA |
| IDS163 |
Analysis of shock decomposition and sensitivity of energetic materials with ReaxFF molecular dynamics |
Zybin, Sergey |
California Institute of Technology |
US |
| IDS164 |
Analysis of carbon cluster formation during high-temperature decomposition of HMX and TATB with ReaxFF reactive molecular dynamics |
Zybin, Sergey |
California Institute of Technology |
US |
| IDS034 |
On the limit of detonation on concentration of liquid explosives` mixtures with diluents |
Dremin, Anatoly |
Institute of Problems of Chemical Physics RAS |
RU |
| IDS102 |
A KINETICS-BASED MODEL FOR SIMULATING DEFORMATION AND DAMAGE IN COMPOSITE SOLID PROPELLANT DURING XDT EVENTS |
Nguyen, Duc |
Lockheed Martin Space Systems Company |
US |
| IDS162 |
Computer modeling of scale effects at heterogeneous HE detonation |
Zherebtsov, Alexey |
Russian Federal Nuclear Center – Institute of Technical Physics |
RU |
