Dynamic Characterization of Soft Materials.- Dynamic Shear Failure of Materials.- Dynamic Response of Glass-Fiber Reinforced Polymer Composites Under Shock Wave Loading.- Dynamic Compressive Strengths of Polymeric Composites: Testing and Modeling.- Transverse Response of Unidirectional Composites Under a Wide Range of Confinements and Strain Rates.- Shock Loading and Failure of Fluid-filled Tubular Structures.- Impact Response and Damage Tolerance of Composite Sandwich Structures.- Failure of Polymer-Based Sandwich Composites Under Shock Loading.- Fiber-Metal Laminate Panels Subjected to Blast Loading.- Sandwich Panels Subjected to Blast Loading.- Advanced Numerical Simulation of Failure in Solids Under Blast and Ballistic Loading: A Review.- Advances in Cohesive Zone Modeling of Dynamic Fracture.
Dynamic Failure of Materials and Structures discusses the topic of dynamic loadings and their effect on material and structural failure. Since dynamic loading problems are very difficult as compared to their static counterpart, very little information is currently available about dynamic behavior of materials and structures. Topics covered include the response of both metallic as well as polymeric composite materials to blast loading and shock loadings, impact loadings and failure of novel materials under more controlled dynamic loads. These include response of soft materials that are important in practical use but have very limited information available on their dynamic response. Dynamic fragmentation, which has re-emerged in recent years has also been included. Both experimental as well as numerical aspects of material and structural response to dynamic loads are discussed.
Written by several key experts in the field, Dynamic Failure of Materials and Structures will appeal to graduate students and researchers studying dynamic loadings within mechanical and civil engineering, as well as in physics and materials science.
Offers a unique approach to a timely topic
Written by leading researchers in the field
Fills a need for graduate students, researchers and industry involved with dynamic materials failure