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High-Pressure Shock Compression of Solids: Response of Highly Porous Solids to Shock Loading, Pt. 4 [Kõva köide]

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  • Formaat: Hardback, 358 pages, kõrgus: 230 mm, kaal: 820 g, 111 illus.
  • Sari: Shock Wave and High Pressure Phenomena
  • Ilmumisaeg: 30-Oct-1997
  • Kirjastus: Springer-Verlag New York Inc.
  • ISBN-10: 038794995X
  • ISBN-13: 9780387949956
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High-Pressure Shock Compression of Solids: Response of Highly Porous Solids to Shock Loading, Pt. 4Suurem pilt
  • Formaat: Hardback, 358 pages, kõrgus: 230 mm, kaal: 820 g, 111 illus.
  • Sari: Shock Wave and High Pressure Phenomena
  • Ilmumisaeg: 30-Oct-1997
  • Kirjastus: Springer-Verlag New York Inc.
  • ISBN-10: 038794995X
  • ISBN-13: 9780387949956
Teised raamatud teemal:
Püsilink: https://www.kriso.ee/db/9780387949956.html
Märksõnad:
Much of the current interest in shock compression of porous solids stems from the desire to bond hard, refractory powders into strong and dense solids. However, while much is known about the effects of shock compression on monolithic materials, the unusual physical and chemical processes that take place when a porous medium is shocked have been little studied thus far. This volume - with contributions by leading researchers in condensed matter physics, physical chemistry, metallurgy, mechanics, and materials science - begins to address that gap. The focus is on heterogeneous deformation mechanisms, nonequilibrium thermodynamics, and chemical processes. The contributions discuss such topics as modeling the complex interplay of thermal, mechanical, and chemical processes; experimental data on pore collapse and their interpretation; and synthesis of new materials through shock-induced chemical reactions. By presenting not only the most recent results, but also the open questions that remain, these essays convey the excitement of developing a scientific basis for understanding shock compression of highly porous solids. Topics covered include: Shock Compression Science in Highly Porous Solids; Shock Loading of Porous High Explosives; Continuum Mixture Modeling of Reactive Porous Media; Two-Phase Media Model of Shock Compression with Chemical reaction; Constitutive Modeling of Shock-Induced Reactions in Powder Mixtures; and, Discrete-element Modeling of Shock Processes in Powders.
Preface v(10) Contributors xv CHAPTER 1 Comments on Shock-Compression Science in Highly Porous Solids 1(22) R. A. Graham 1.1. Introduction 1(2) 1.2. Macroscopic Deformation Characteristics of Powder Compacts 3(2) 1.3. Scientific Issues and Tools 5(6) 1.4. Materials Science Observations 11(3) 1.5. Time-Resolved Stress Measurements 14(2) 1.6. Conclusions 16(1) Acknowledgments 17(1) References 18(5) CHAPTER 2 Shock Loading of Porous High Explosives 23(40) S. A. Sheffield R. L. Gustavsen M. U. Anderson 2.1. Introduction 23(2) 2.2. Porous Distended Materials in General 25(2) 2.3. Equations of State for Porous Explosives 27(8) 2.4. Compaction Waves 35(7) 2.5. Shock Initiation of Porous Explosives 42(10) 2.6. Detonation in Porous Explosives 52(4) 2.7. Summary 56(2) Acknowledgment 58(1) References 58(5) CHAPTER 3 Continuum Mixture Modeling of Reactive Porous Media 63(20) M. R. Baer 3.1. Introduction 63(1) 3.2. Theoretical Foundations 64(10) 3.3. Model Application to Shock Impact Experiments 74(6) 3.4. Summary 80(1) References 81(2) CHAPTER 4 Two-Phase Media Model of Shock Compression with Chemical Reaction 83(22) N. Kh. Akhmadeev 4.1. Introduction 83(2) 4.2. Two-Constituent Model of a Power Mixture Undergoing Chemical Reaction 85(9) 4.3. Numerical and Acoustic Analysis of Wave Processes in Three-Layer Target Containing a Cell with SnS Sn+S Powder Mixture 94(7) 4.4. Concluding Remarks 101(1) Acknowledgments 102(1) References 102(3) CHAPTER 5 Developments in Constitutive Modeling of Shock-Induced Reactions in Powder Mixtures 105(38) L. S. Bennett K. Tanaka Y. Horie 5.1. Introduction 105(3) 5.2. Comparative Features of the Reactive Models 108(2) 5.3. Equivalence of the Reactive Models 110(2) 5.4. Generalized VIR with Mass Transport and Chemical Reaction 112(17) 5.5. Model Calculations 129(6) 5.6. Conclusions 135(1) Acknowledgments 135(1) Appendix 135(7) References 142(1) CHAPTER 6 Discrete Meso-Element Modeling of Shock Processes in Powders 143(34) Z. P. Tang Y. Horie S. G. Psakhie 6.1. Introduction 143(1) 6.2. Theory of the Discrete Meso-Dynamic Method 144(13) 6.3. Determination of Material Parameters 157(4) 6.4. Modeling Calculations of Shock Process in Powder Materials 161(13) 6.5. Conclusion 174(1) Acknowledgments 174(1) References 174(3) CHAPTER 7 Recent Developments in Modeling Shock Compression of Porous Materials 177(28) W. Tong G. Ravichandran 7.1. Introduction 177(1) 7.2. Pore Collapse 178(7) 7.3. Shock Compression 185(9) 7.4. Shock Wave Propagation in Porous Materials 194(5) 7.5. Summary 199(1) Acknowledgment 200(1) References 200(5) CHAPTER 8 Elastic-Plastic Waves in Porous Materials 205(28) V. M. Fomin S. P. Kiselev 8.1. Introduction 205(1) 8.2. Mathematical Models of Porous Materials 205(2) 8.3. Mathematical Model of a Porous Elastic-Plastic Material 207(8) 8.4. Numerical Simulation of Shock Wave Propagation in Porous Aluminum and Iron 215(8) 8.5. Expansion Shock Wave in Porous Material 223(6) List of Symbols 229(2) References 231(2) CHAPTER 9 The Numerical Simulation of the Dynamic Compaction of Powders 233(24) David J. Benson 9.1. Introduction 233(1) 9.2. An Eulerian Hydrocode Formulation 234(7) 9.3. Specialized Hydrocode Development for Shock Compaction 241(4) 9.4. Verification of the Bulk Response 245(3) 9.5. Predicted Powder Morphologies 248(5) 9.6. Summary 253(1) Acknowledgments 253(1) References 253(4) CHAPTER 10 Materials Issues in Shock-Compression-Induced Chemical Reactions in Porous Solids 257(32) N. N. Thadhani T. Aizawa 10.1. Introduction 257(1) 10.2. Materials Issues 258(2) 10.3. Shock-Compression Characteristics 260(7) 10.4. Process Mechanisms of Shock-Induced Reactions 267(15) 10.5. Summary and Concluding Remarks 282(1) Acknowledgments 283(1) References 284(5) CHAPTER 11 Shock Synthesis of Materials 289(20) T. Sekine 11.1. Introduction 289(1) 11.2. Experimental Techniques 289(2) 11.3. Shock Synthesis 291(12) 11.4. Concluding Remarks 303(1) References 303(6) CHAPTER 12 Magnetic Response of Powders to Shock Loading and Fabrication of Nanocrystalline Magnets 309(22) K. Kondo 12.1. Introduction 309(1) 12.2. Estimation of the Continuum Shock State 310(3) 12.3. In-Situ Measurements of Magnetization 313(7) 12.4. Magnetic Properties of Shock-Consolidated Powder 320(9) 12.5. Conclusion 329(1) References 329(2) Author Index 331(8) Subject Index 339