Continuum mixture theory and mesoscale modeling are applied to describe the behavior of shock-loaded heterogeneous media. One-dimensional simulations of gas-gun experiments demonstrate that the wave features are well described by mixture theory, including reflected wave behavior and conditions where significant reaction is initiated. Detailed wave fields are resolved in numerical simulations of impact on a lattice of discrete explosive {open_quotes}crystals{close_quotes}. It is shown that rapid distortion first occurs at material contact points; the nature of the dispersive fields includes large amplitude fluctuations of stress over several particle pathlengths. Localization of energy causes {open_quotes}hot-spots{close_quotes} due to shock...
This book is the first of several volumes on solids in the Shock Wave Science and Technology Referen...
The fluid-structure interaction of reacting materials requires computational models capable of resol...
This book, as a volume of the Shock Wave Science and Technology Reference Library, is primarily conc...
The mesoscopic processes of consolidation, deformation and reaction of shocked porous energetic mate...
In this work, the mesoscale processes of consolidation, deformation and reaction of shocked porous e...
The field of shock physics as a whole has only recently begun to pay particular attention to modelin...
Three-dimensional numerical simulations and line-imaging optically recorded velocity interferometer ...
We study the problem of impact-induced shock wave propagation through a model one-dimensional hetero...
The investigation of the heterogeneous material response on microscopic level at a high speed load i...
Shock waves (SW) in "gas - solid particles" mixtures and in porous elastoplastic materials...
Wave dispersion in heterogeneous solids due to scattering within the microstructure is examined. Und...
In this mini-review we summarize the progress of modeling, simulation and analysis of shock response...
A multiphase continuum mixture theory is presented that couples the mechanical response, damage evol...
It has long been known that there are fundamental differences between homogeneous and heterogeneous ...
In contrast to conventional explosives which constitute rapid decomposition of the molecular structu...
This book is the first of several volumes on solids in the Shock Wave Science and Technology Referen...
The fluid-structure interaction of reacting materials requires computational models capable of resol...
This book, as a volume of the Shock Wave Science and Technology Reference Library, is primarily conc...
The mesoscopic processes of consolidation, deformation and reaction of shocked porous energetic mate...
In this work, the mesoscale processes of consolidation, deformation and reaction of shocked porous e...
The field of shock physics as a whole has only recently begun to pay particular attention to modelin...
Three-dimensional numerical simulations and line-imaging optically recorded velocity interferometer ...
We study the problem of impact-induced shock wave propagation through a model one-dimensional hetero...
The investigation of the heterogeneous material response on microscopic level at a high speed load i...
Shock waves (SW) in "gas - solid particles" mixtures and in porous elastoplastic materials...
Wave dispersion in heterogeneous solids due to scattering within the microstructure is examined. Und...
In this mini-review we summarize the progress of modeling, simulation and analysis of shock response...
A multiphase continuum mixture theory is presented that couples the mechanical response, damage evol...
It has long been known that there are fundamental differences between homogeneous and heterogeneous ...
In contrast to conventional explosives which constitute rapid decomposition of the molecular structu...
This book is the first of several volumes on solids in the Shock Wave Science and Technology Referen...
The fluid-structure interaction of reacting materials requires computational models capable of resol...
This book, as a volume of the Shock Wave Science and Technology Reference Library, is primarily conc...