Prediction of Unreacted Shock Hugoniot Compression Curve for Condensed Phase High Explosives

Kunihito Nagayama; Shiro Kubota

doi:10.4028/www.scientific.net/MSF.465-466.445

Paper Titles

Calculation of Dynamic Strain Energy Release Rates due to Shock Wave Loading
p.415

Nonideal Blast Waves from Heterogeneous Explosives
p.421

The Effect of the Heat Treatment on Residual Stresses in HVOF Sprayed WC-Co Coating
p.427

Comparative Study of Al/SiC_p Composites Manufactured by Direct and Underwater Explosive Compaction
p.433

Numerical Studies of Wave Generation Using Spiral Detonating Cord
p.439

Prediction of Unreacted Shock Hugoniot Compression Curve for Condensed Phase High Explosives
p.445

Some Studies on the Developments of Explosive Metal Processing Technology
p.453

Microstructure of Bonding Interface in Explosively-Welded Clads and Bonding Mechanism
p.465

Detonation Propagation in Packed Beds of Aluminum Saturated with Nitromethane
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Prediction of Unreacted Shock Hugoniot Compression Curve for Condensed Phase High Explosives

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Materials Science Forum (Volumes 465-466)

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445-452

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https://doi.org/10.4028/www.scientific.net/MSF.465-466.445

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September 2004

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Kunihito Nagayama, Shiro Kubota

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Energetic Material, Equation of State, Grüneisen Parameter, Shock Hugoniot, Slater Model

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