Structure-property relationships under extreme dynamic environments : : shock recovery experiments /
By: Williams, Cyril L [author.].
Contributor(s): Zimmerman, Kristin B [editor.].
Material type:
BookSeries: Synthesis digital library of engineering and computer science: ; Synthesis SEM lectures on experimental mechanics: # 4Publisher: San Rafael [California] : Morgan & Claypool Publishers, 2019.Description: 1 online resource (xii, 143 pages.) : illustrations.Content type: text Media type: electronic Carrier type: online resourceISBN: 9781681734538; 1681734532.Subject(s): Materials -- Mechanical properties -- Study and teaching | Materials -- Compression testing | shock compression | high strain rate mechanics | dislocation slip | twining | texture evolution | microstructure evolution | phase transformationGenre/Form: Electronic books.DDC classification: 620.1126 Online resources: Abstract with links to resource | Abstract with links to full text Also available in print.| Item type | Current location | Call number | Status | Date due | Barcode | Item holds |
|---|---|---|---|---|---|---|
E books
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PK Kelkar Library, IIT Kanpur | Available | EBKE799 |
Mode of access: World Wide Web.
Part of: Synthesis digital library of engineering and computer science.
Includes bibliographical references (pages 111-142).
Intro; Preface; Introduction; Historical Perspective on the Structure-Property Relationships Pertaining to Shock Compression Science; Historical Perspective on the Structure-Property Relationships Pertaining to Shock Compression Science; A Brief Biography of Cyril Stanley Smith; Plastic Deformation in Shock Compressed Metals and Metallic Alloys; Plastic Deformation in Shock Compressed Metals and Metallic Alloys; Deformation Slip; Deformation Twinning; Spall Failure in Metals and Metallic Alloys; Bridging the Knowledge Gap in Shock Recovery Experiments
Shock Wave Propagation in Condensed MediaLinear Elastic Material; Shock Waves in Condensed Media; Shock Formation; Shock Stability; Rarefaction Waves; Rankine-Hugoniot Jump Relations; Equation of State; Elastic-Plastic Material Response; Shock Recovery Experiments; Rogue Edge Radial Release Waves; Gas/Powder Gun-Driven Recovery Experiments; Explosive-Driven Recovery Experiments; Deformation Mechanisms and Spall Failure; Mechanical Property Changes in Shock Compressed Metals; Microstructure Changes in Shock Compressed Metals; Substructure in Shock Compressed Metals with FCC Lattice Structure
Substructure in Shock-Compressed Metals with BCC Lattice StructureSubstructure in Shock-Compressed Metals with HCP Lattice Structure; Failure Mechanisms and Spallation in Shock Compressed Metals; Spallation in Metals with FCC Lattice Structure; Spallation in Metals with BCC Lattice Structure; Spallation in Metals with HCP Lattice Structure; Microstructure of Explosively Compacted Powders and Powder Mixtures; Microstructure of Explosively Compacted Powders and Powder Mixtures; The New Frontier in Shock Recovery Experiments; References; Author's Biography; Blank Page
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The inelastic response and residual mechanical properties acquired from most shock compressed solids are quite different from those acquired from quasi-static or moderate strain rates. For instance, the residual hardness of many shock compressed metals has been found to be considerably lower than those loaded under quasi-static conditions to the same maximum stress. However, the residual hardness of shock compressed metals is much higher than those loaded quasi-statically to the same total strain. These observations suggest that the deformation mechanisms active during inelastic deformation under shock compression and quasi-static or moderate rates may be quite different. Therefore, the primary objective of this short book is to offer the reader a concise introduction on the Structure-Property relationships concerning shock compressed metals and metallic alloys via shock recovery experiments. The first phase of the book, chapters 1 through 3 provides a brief historical perspective on the structure-property relationships as it pertains to shock compression science, then plastic deformation in shock compressed metals and metallic alloys is described in terms of deformation slip, deformation twinning, and their consequences to spall failure. Existing knowledge gaps and limitations on shock recovery experiments are also discussed. The fundamentals of shock wave propagation in condensed media are presented through the formation and stability of shock waves, then how they are treated using the Rankine-Hugoniot jump relations derived from the conservation of mass, momentum, and energy. The equation of states which govern the thermodynamic transition of a material from the unshock state to the shock state is briefly described and the elastic-plastic behavior of shock compressed solids is presented at the back end of the first phase of this book. The second phase of the book describes the geometry and design of shock recovery experiments using explosives, gas and powder guns. Then results derived from the residual mechanical properties, microstructure changes, and spall failure mechanisms in shock compressed metals and metallic alloys with FCC, BCC, and HCP crystal lattice structures are presented. Also, results on the residual microstructure of explosively compacted powders and powder mixtures are presented. Lastly, the book closes with the new frontiers in shock recovery experiments based on novel materials, novel microscopes, novel mechanical processing techniques, and novel time-resolved in-situ XRD shock experiments.
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