Ceramic Materials for Energy Applications VI, Volume 37, Issue 6

1 - Ceramic Materials for Energy Applications VI [Seite 3]
2 - Contents [Seite 7]
3 - Preface [Seite 9]
4 - Introduction [Seite 11]
5 - Advanced Materials for Sustainable Nuclear Fission and Fusion Energy [Seite 15]
5.1 - LOW TEMPERATURE AIR BRAZE PROCESS FOR JOINING SILICON CARBIDE COMPONENTS USED IN HEAT EXCHANGERS, FUSION AND FISSION REACTORS, AND OTHER ENERGY PRODUCTION AND CHEMICAL SYNTHESIS SYSTEMS [Seite 17]
5.1.1 - ABSTRACT [Seite 17]
5.1.2 - 1. INTRODUCTION [Seite 17]
5.1.3 - 2. EXPERIMENTAL [Seite 18]
5.1.3.1 - 2.1. Materials - Joint Initiator [Seite 18]
5.1.3.2 - 2.2. SiC Substrates used for Joining [Seite 18]
5.1.3.3 - 2.3 Joined Specimens for Shear, Tensile, and Torsion Strength Testing [Seite 18]
5.1.3.4 - 2.4 Joined Specimens for High Temperature Oxygen and Saturated Steam Corrosion Test [Seite 20]
5.1.3.5 - 2.5 Hermetic Seal Study [Seite 20]
5.1.3.6 - 2.6 Joint Annealing Study: Insitu Joint Microstructural Evolution as a Function of High Temperature Hold Time [Seite 21]
5.1.4 - 3. RESULTS AND DISCUSSION [Seite 21]
5.1.4.1 - 3.1 Shear, Tensile, and Torsion Test Results [Seite 21]
5.1.4.2 - 3.2 Hermetic Seal Results [Seite 25]
5.1.4.3 - 3.3 Joint Annealing Study: Results of In-situ Joint Microstructural Evolution as a Function of High Temperature Hold Time [Seite 26]
5.1.5 - 4. SUMMARY AND CONCLUSIONS [Seite 29]
5.1.6 - ACKNOWLEDGEMENTS [Seite 29]
5.1.7 - REFERENCES [Seite 30]
5.2 - COMPOSITION, STRUCTURE, MANUFACTURE, AND PROPERTIES OF SIC-SIC CMCS FOR NUCLEAR APPLICATIONS: INFORMATIONAL CHAPTERS IN THE ASME BPV CODE SECTION III [Seite 31]
5.2.1 - ABSTRACT [Seite 31]
5.2.2 - INTRODUCTION [Seite 31]
5.2.3 - ASME BOILER AND PRESSURE VESSEL CODE [Seite 32]
5.2.4 - SECTION III - CONSTRUCTION OF NUCLEAR FACILITIES [Seite 33]
5.2.5 - NEW APPENDICES [Seite 35]
5.2.6 - CONCLUSIONS [Seite 36]
5.2.7 - ACKNOWLEDGEMENT [Seite 36]
5.2.8 - REFERENCES [Seite 36]
5.3 - HOOP TENSILE STRENGTH OF COMPOSITE TUBES FOR LWRS APPLICATIONS USING INTERNAL PRESSURIZATION: TWO ASTM TEST METHODS [Seite 37]
5.3.1 - ABSTRACT [Seite 37]
5.3.2 - INTRODUCTION [Seite 37]
5.3.3 - ASTM STANDARD TEST METHODS [Seite 39]
5.3.4 - SCOPE AND APPLICATION [Seite 40]
5.3.5 - EXPERIMENTAL FACTORS [Seite 40]
5.3.6 - TEST SPECIMEN GEOMETRIES [Seite 41]
5.3.7 - TEST EQUIPMENT AND PROCEDURES [Seite 41]
5.3.8 - CALCULATION, REPORTING, PRECISION AND BIAS [Seite 42]
5.3.9 - CURRENT STATUS AND FUTURE WORK [Seite 43]
5.3.10 - CONCLUSIONS [Seite 43]
5.3.11 - ACKNOWLEDGEMENT [Seite 43]
5.3.12 - REFERENCES [Seite 43]
5.4 - USED FUEL CONTENT VERIFICATION USING LEAD SLOWING DOWN SPECTROSCOPY [Seite 45]
5.4.1 - ABSTRACT [Seite 45]
5.4.2 - INTRODUCTION [Seite 45]
5.4.3 - DESIGN OF THE MODEL [Seite 46]
5.4.4 - RESULTS [Seite 47]
5.4.5 - DISCUSSION AND CONCLUSION [Seite 48]
5.4.6 - REFERENCES [Seite 49]
5.5 - APPLICATION OF SELECTIVE AREA LASER DEPOSITION TO THE MANUFACTURE OF SIC-SIC COMPOSITE NUCLEAR FUEL CLADDING [Seite 51]
5.5.1 - ABSTRACT [Seite 51]
5.5.2 - INTRODUCTION [Seite 51]
5.5.3 - NUCLEAR BACKGROUND [Seite 52]
5.5.4 - ACCIDENT TOLERANT FUEL: SILICON CARBIDE [Seite 53]
5.5.5 - SELECTIVE AREA LASER DEPOSITION [Seite 55]
5.5.6 - PREVIOUS SALD WORK AT MANCHESTER [Seite 56]
5.5.7 - EXPERIMENTAL IMPROVEMENTS [Seite 57]
5.5.8 - DEPOSITED SAMPLES AND PROCESS PROBLEMS [Seite 58]
5.5.8.1 - Laser Beam Ablation [Seite 58]
5.5.8.2 - Substrate Changes [Seite 59]
5.5.9 - FUTURE WORK [Seite 61]
5.5.10 - ACKNOWLEDGEMENTS [Seite 61]
5.5.11 - REFERENCES [Seite 61]
5.6 - SYNTHESIS OF HIGH PURITY Li5ALO4 POWDER BY SOLID STATE REACTION UNDER THE H2 FIRING [Seite 63]
5.6.1 - ABSTRACT [Seite 63]
5.6.2 - INTRODUCTION [Seite 63]
5.6.3 - EXPERIMENTAL [Seite 64]
5.6.4 - CHARACTERIZATION [Seite 64]
5.6.5 - RESULTS AND DISCUSSION [Seite 64]
5.6.6 - CONCLUSIONS [Seite 73]
5.6.7 - ACKNOWLEDGEMENTS [Seite 73]
5.6.8 - REFERENCES [Seite 73]
5.7 - LASER-PRINTED CERAMIC FIBER RIBBONS: PROPERTIES AND APPLICATIONS [Seite 75]
5.7.1 - ABSTRACT [Seite 75]
5.7.2 - INTRODUCTION [Seite 75]
5.7.3 - EXPERIMENTAL [Seite 76]
5.7.4 - RESULTS [Seite 78]
5.7.4.1 - Chemistry [Seite 78]
5.7.4.2 - Mechanical Testing and Performance [Seite 79]
5.7.4.3 - Morphology [Seite 80]
5.7.5 - DISCUSSION [Seite 80]
5.7.5.1 - FFF Nuclear Fuel-In-Fiber Design [Seite 82]
5.7.6 - CONCLUSIONS [Seite 84]
5.7.7 - REFERENCES [Seite 84]
5.7.8 - Acknowledgment [Seite 85]
5.8 - DEVELOPMENT OF CAULKED JOINT BETWEEN ZIRCALOY AND SiC/SiC COMPOSITE TUBES BY USING DIODE LASER [Seite 87]
5.8.1 - ABSTRACT [Seite 87]
5.8.2 - INTRODUCTION [Seite 87]
5.8.3 - EXPERIMENTAL PROCEDURE [Seite 88]
5.8.4 - WELDABILITY OF ZIRCALOY TUBE [Seite 89]
5.8.5 - ZIRCALOY & SiC/SiC COMPOSITE TUBES WITHOUT TITANIUM POWDER [Seite 90]
5.8.6 - ZIRCALOY & SiC/SiC COMPOSITE TUBES WITH TITANIUM POWDER [Seite 92]
5.8.7 - Conclusions [Seite 94]
5.8.8 - References [Seite 95]
6 - Advanced Ceramic Materials and Processing for Photonics and Energy [Seite 97]
6.1 - PROCESSING AND OPTICAL PROPERTIES OF GE-CORE FIBERS [Seite 99]
6.1.1 - ABSTRACT [Seite 99]
6.1.2 - INTRODUCTION [Seite 99]
6.1.3 - EXPERIMENTAL WORK [Seite 100]
6.1.4 - RESULTS [Seite 102]
6.1.4.1 - Transmission Measurements [Seite 102]
6.1.4.2 - Composition Measurements [Seite 103]
6.1.5 - CONCLUSION [Seite 104]
6.1.6 - ACKNOWLEDGEMENT [Seite 104]
6.1.7 - REFERENCES [Seite 104]
6.2 - DEVELOPMENT OF TRANSTHICKNESS TENSION TEST METHOD FOR CERAMIC MATRIX COMPOSITES AT ELEVATED TEMPERATURES [Seite 107]
6.2.1 - ABSTRACT [Seite 107]
6.2.2 - 1. INTRODUCTION [Seite 107]
6.2.3 - 2. Concept [Seite 108]
6.2.3.1 - 2.1 SGT [Seite 108]
6.2.3.2 - 2.2 QNT [Seite 109]
6.2.4 - 3. EXPERIMENT [Seite 110]
6.2.4.1 - 3.1 Material [Seite 110]
6.2.4.2 - 3.2 Test [Seite 111]
6.2.4.3 - 3.3 Numerical Analysis [Seite 111]
6.2.5 - 4. Result [Seite 112]
6.2.6 - 5. DISCUSSION [Seite 115]
6.2.7 - 6. CONCLUSION [Seite 116]
6.2.8 - 7. ACKNOWLEDGEMENT [Seite 116]
6.2.9 - REFERENCES [Seite 116]
6.3 - MICROSTRUCTURE ANALYSIS OF THE EPITAXIAL GROWTH OF Cu2O ON GOLD NANO-ISLANDS [Seite 117]
6.3.1 - ABSTRACT [Seite 117]
6.3.2 - INTRODUCTION [Seite 117]
6.3.3 - GOLD NANOISLANDS FOR SEEDING GROWTH [Seite 118]
6.3.4 - EXPERIMENTAL [Seite 119]
6.3.5 - CHARACTERIZATION [Seite 119]
6.3.6 - DISCUSSION [Seite 123]
6.3.7 - BIBLIOGRAPHY [Seite 123]
6.4 - DEVELOPMENT OF LOW TEMPERATURE ALUMINOPHOSPHATE GLASS SYSTEMS FOR HIGH EFFICIENCY LIGHTING DEVICES [Seite 127]
6.4.1 - ABSTRACT [Seite 127]
6.4.2 - INTRODUCTION [Seite 127]
6.4.3 - EXPERIMENTAL [Seite 128]
6.4.4 - RESULTS AND DISCUSSION [Seite 129]
6.4.4.1 - Characterization of Glass Systems [Seite 129]
6.4.4.2 - GCP Layer Fabrication and Evaluation [Seite 131]
6.4.4.3 - Optical Performance of GCP Layer [Seite 133]
6.4.5 - CONCLUSIONS [Seite 135]
6.4.6 - ACKNOWLEDGEMENT [Seite 136]
6.4.7 - REFERENCES [Seite 136]
7 - Advanced Materials and Technologies for Energy Generation, Conversion, and Rechargeable Energy Storage [Seite 139]
7.1 - DIELECTRIC, STRUCTURAL AND SPECTROSCOPIC PROPERTIES OF Mg-DOPED CaCu3Ti4O12 CERAMICS BY THE SOLID-STATE REACTION METHOD [Seite 141]
7.1.1 - ABSTRACT [Seite 141]
7.1.2 - INTRODUCTION [Seite 141]
7.1.3 - EXPERIMENTAL [Seite 142]
7.1.4 - RESULTS AND DISCUSSION [Seite 142]
7.1.5 - CONCLUSIONS [Seite 146]
7.1.6 - ACKNOWLEDGEMENTS [Seite 146]
7.1.7 - REFERENCES [Seite 146]
7.2 - STRUCTURAL AND DIELECTRIC PROPERTIES OF (1-x) Li2TiO3 + xMgO CERAMICS PREPARED BY THE SOLID STATE REACTION METHOD [Seite 149]
7.2.1 - ABSTRACT [Seite 149]
7.2.2 - INTRODUCTION [Seite 149]
7.2.3 - EXPERIMENTAL [Seite 150]
7.2.4 - RESULTS AND DISCUSSION [Seite 150]
7.2.5 - CONCLUSIONS [Seite 154]
7.2.6 - REFERENCES [Seite 154]
7.3 - LITHIUM LOSS INDICATED FORMATION OF MICROCRACKS IN LATP CERAMICS [Seite 157]
7.3.1 - ABSTRACT [Seite 157]
7.3.2 - INTRODUCTION [Seite 157]
7.3.3 - EXPERIMENTAL [Seite 158]
7.3.4 - RESULTS AND DISCUSSION [Seite 158]
7.3.5 - CONCLUSION [Seite 163]
7.3.6 - REFERENCES [Seite 163]
8 - Author Index [Seite 165]
9 - EULA [Seite 167]