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Index
Cover Title page Copyright page Dedication page Acknowledgments Contributors List 1 Introduction
1.1 Background 1.2 Ultra-High Temperature Ceramics 1.3 Description of Contents References
2 A Historical Perspective on Research Related to Ultra-High Temperature Ceramicsa
2.1 Ultra-High Temperature Ceramics 2.2 Historic Research 2.3 Initial NASA Studies 2.4 Research Funded by the Air Force Materials Laboratory 2.5 Summary Acknowledgments References
3 Reactive Processes for Diboride-Based Ultra-High Temperature Ceramics
3.1 Introduction 3.2 Reactive Processes for the Synthesis of Diboride Powders 3.3 Reactive Processes for Oxygen Removing during Sintering 3.4 Reactive Sintering Processes 3.5 Summary References
4 First-Principles Investigation on the Chemical Bonding and Intrinsic Elastic Properties of Transition Metal Diborides TMB2 (TM=Zr, Hf, Nb, Ta, and Y)
4.1 Introduction 4.2 Calculation Methods 4.3 Results and Discussion 4.4 Conclusion Remarks Acknowledgment References
5 Near-Net-Shaping of Ultra-High Temperature Ceramics
5.1 Introduction 5.2 Understanding Colloidal Systems: Interparticle Forces 5.3 Near-Net-Shape Colloidal Processing Techniques 5.4 Summary, Recommendations, and Path Forward Acknowledgments References
6 Sintering and Densification Mechanisms of Ultra-High Temperature Ceramics
6.1 Introduction 6.2 MB2 with Metals 6.3 MB2 with Nitrides 6.4 MB2 with Metal Disilicides 6.5 MB2 with Carbon or Carbides 6.6 MB2 with SiC 6.7 MB2–SiC Composites with Third Phases 6.8 Effects of Sintering Aids on High-Temperature Stability 6.9 Transition Metal Carbides 6.10 Conclusions Acknowledgments References
7 UHTC Composites for Hypersonic Applications
7.1 Introduction 7.2 Preparation of Continuous-Fiber-Reinforced UHTC Composites 7.3 UHTC Coatings 7.4 Short-Fiber-Reinforced UHTC Composites 7.5 Hybrid UHTC Composites 7.6 Summary and Future Prospects References
8 Mechanical Properties of Zirconium-Diboride Based UHTCs
8.1 Introduction 8.2 Room Temperature Mechanical Properties 8.3 Elevated-Temperature Mechanical Properties 8.4 Concluding Remarks References
9 Thermal Conductivity of ZrB2 and HfB2
9.1 Introduction 9.2 Conductivity of ZrB2 and HfB2 9.3 ZrB2 and HfB2 Composites 9.4 Electron and Phonon Contributions to Thermal Conductivity 9.5 Concluding Remarks References
10 Deformation and Hardness of UHTCs as a Function of Temperature
10.1 Introduction 10.2 Elastic Properties 10.3 Hardness 10.4 Hardness and Yield Strength 10.5 Deformation Mechanism Maps 10.6 Lattice Resistance to Dislocation Glide 10.7 Dislocation Glide Controlled by Other Obstacles 10.8 Deformation by Creep 10.9 Deformation of Carbides versus Borides 10.10 Conclusions References
11 Modeling and Evaluating the Environmental Degradation of UHTCs under Hypersonic Flow
11.1 Introduction 11.2 Oxidation Modeling 11.3 UHTC Behavior under Simulated Hypersonic Conditions 11.4 Comparing Model Predictions to Leading-Edge Behavior 11.5 Behavior of UHTCs under Other Test Methods 11.6 Summary References
12 Tantalum Carbides: Their Microstructures and Deformation Behavior
12.1 Crystallography of Tantalum Carbides 12.2 Microstructures of Tantalum Carbides 12.3 Mechanical Properties of Tantalum Carbides 12.4 Summary Acknowledgments References
13 Titanium Diboride
13.1 Introduction 13.2 Phase Diagram, Crystal Structure, and Bonding 13.3 Synthesis of Titanium Diboride Powders 13.4 Densification of Transition Metal Borides 13.5 Mechanical Properties at Ambient and Elevated Temperatures 13.6 Physical Properties and Oxidation Resistance 13.7 Oxidation Resistance 13.8 Tribological Properties 13.9 Applications of TiB2 13.10 Conclusions References
14 The Group IV Carbides and Nitrides
14.1 Background 14.2 Group IV Carbides 14.3 Preparation and Processing 14.4 Mechanical and Physical Properties 14.5 Oxidation of the UHTC Carbides and Nitrides 14.6 Oxidation of the UHTC Carbides 14.7 UHTC Nitrides 14.8 Preparation, Diffusion, and Phase Formation 14.9 Mechanical and Physical Properties 14.10 Oxidation of Nitrides 14.11 Conclusions and Future Research Acknowledgments References
15 Nuclear Applications for Ultra-High Temperature Ceramics and MAX Phases
15.1 Future Nuclear Reactors 15.2 Current Nuclear Ceramics 15.3 Future Nuclear Ceramics 15.4 Non-Oxide Nuclear Fuels 15.5 Other Possible Future Fission and Fusion Applications 15.6 Thermodynamics of Nuclear Systems 15.7 Conclusions References
16 UHTC-Based Hot Structures
16.1 Introduction 16.2 TPS: Test Articles and Prototypes 16.3 Plasma Tests of Nose Test Articles 16.4 Expert Project: Computational Fluid Dynamics Computations and Plasma Tests 16.5 In-Fling Testing of the Capsule “SHARK” 16.6 Future Work References
Index End User License Agreement
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