Jonathan Salem is a Materials Research Engineer at NASA Glenn Research Center in Cleveland, OH. He received a BS in Materials Science and Metallurgical Engineering from theUniversity ofCincinnati in 1983 and worked at NASA-Lewis as a Materials Research Engineer for two years performing heat treatment and fracture studies of titanium and steel alloys. In 1987 he received an MS in Materials Science from theUniversity ofWashington,Seattle and served at NASA–Glenn as Project Leader of the Toughened Ceramics Life Prediction Program on development of mechanical testing methods and standards for ceramic materials. In 1999 he received a PhD in Mechanical engineering from the University of Washington. Presently, he is involved with the room and elevated temperature mechanical testing and reliability modeling of ceramic, intermetallic and composite materials for the Life Prediction, where briefly served as a temporary Deputy Branch Chief. Prior to working at NASA, he worked in Quality Assurance at Powell Valve,Cincinnati,OH, and at Forest City Foundries, Cleveland, OH. He authored or co-authored over 60 archival publications, over 70 proceedings publications, and four national and international standards on mechanics of ceramics. He is a fellow of American Society for Testing and Materials and received a NASA Manned Spaced Flight Awareness Award for work on ceramic bearings for the Space Shuttle Main Engine Turbo-pump. In 2004, he received the Richard M. Fulrath Award from the American Ceramic Society for development of technical standards for design of structural ceramics.
Dongming Zhu is a senior Materials Research Engineer at Army Research Laboratory, Vehicle Technology Directorate, and Durability and Protective Coatings Branch of Structures and Materials Division, at NASA Glenn Research Center. His expertise covers the areas of thermal conductivity, lattice defects and transport, high temperature oxidation, high-heat-flux testing, and mechanical behavior of ceramic coating systems, with an emphasis on experimental investigation and analytical modeling of processing, thermal fatigue and fracture behavior of advanced protective coatings and composites. His major contributions include the development of low conductivity thermal barrier coatings for turbine airfoil applications, 1650°C thermal/environmental barrier coatings for SiC/SiC ceramic matrix composite (CMC) turbine vane and combustor liner applications. He has authored more than 100 archival publications and three patents. He is a member of the American Ceramic Society and ASM, International, has been a lead organizer for several International Symposia. He is currently the Chair-elect of the Engineering Ceramic Division of the American Ceramic Society, and an associate editor of the International Journal of Applied Ceramic Technology. He has received several awards from NASA and professional societies. He received his Ph.D. degree in Chemical Engineering and Materials Science from the University of Minnesota in 1996.
Preface | p. ix |
Introduction | p. xi |
Advanced Dielectric, Piezoelectric and Ferroelectric Materials | |
Lead Strontium Zirconate Titanate (PSZT) Thin Films for Tunable Dielectric Applications | p. 3 |
Nanosize Engineered Ferroelectric/Dielectric Single and Multilayer Films for Microwave Applications | p. 9 |
Construction and Characterization of (Y,Yb)MnO[subscript 3]/HfO[subscript 2] Stacking Layers for Application to FeRAM | p. 17 |
Temperature Dependence on the Structure and Property of Li[subscript 0.06](Na[subscript 0.5]K[subscript 0.5])[subscript 0.94]NbO[subscript 3] Piezoceramics | p. 25 |
Polar Axis Orientation and Electrical Properties of Alkoxy-Derived One Micro-Meter-Thick Ferro-/Piezoelectric Films | p. 33 |
Processing of Porous Li[subscript 0.06](Na[subscript 0.5]K[subscript 0.5])[subscript 0.94]NbO[subscript 3] Ceramics and Their Piezoelectric Composites with Hetero-Crystals | p. 43 |
Electric-Field-Induced Dielectric, Domain and Optical Phenomena in High-Strain Pb(In[subscript fraction12]Nb[subscript fraction12])[subscript 1-x]Ti[subscript x]O[subscript 3] (x=0.30) Single Crystal | p. 49 |
Effects of Electric Field on the Biaxial Strength of Poled PZT | p. 57 |
Piezoelectric Ceramic Fiber Composites for Energy Harvesting and Active Structural Control | p. 69 |
Dielectric Property of Resin-Based Composites Dispersing Ceramic Filler Particles | p. 79 |
The Effect of Sintering Conditions and Dopants on the Dielectric Loss of the Giant Dielectric Constant Perovskite CaCu[subscript 3]Ti[subscript 4]O[subscript 12] | p. 87 |
Electroceramic Materials for Sensors | |
Multifunctional Potentiometric Gas Sensor Array with an Integrated, Heater and Temperature Sensors | p. 101 |
Prussian Blue Nanoparticles Encapsulated Within Ormosil Film | p. 109 |
Gas-Sensing Property of Highly Selective NO[subscript x] Decomposition Electrochemcial Reactor | p. 125 |
The Structure, Electrical and CO-Sensing Properties of Perovskite- Type La[subscript 0.8]Pb[subscript 0.2]Fe[subscript 0.8]Cu[subscript 0.2]O[subscript 3] Ceramic | p. 133 |
NiCr[subscript 2]O[subscript 4] and NiO Planar Impedance-NO[subscript x] Sensors for High Temperature Applications | p. 141 |
Thermoelectric Materials for Power Conversion Applications | |
The Development of Thermoelectric Oxides with Perovskite-Type Structures for Alternative Energy Technologies | p. 151 |
Power Generation of p-Type Ca[subscript 3]Co[subscript 4]O[subscript 9]/n-Type CaMnO[subscript 3] Module | p. 161 |
Thermoelectric Properties of Pb and Sr Doped Ca[subscript 3]Co[subscript 4]O[subscript 9] | p. 171 |
Thermoelectric Properties of Mix-Crystal Compound Mg[subscript 2]Si-Mg[subscript 3]Sb[subscript 2] | p. 185 |
Thermoelectric Performance of Doped SrO(SrTiO[subscript 3])n (n = 1, 2) Ruddlesden-Popper Phases | p. 193 |
Growth of Bi[subscript 2]Ca[subscript 2]Co[subscript 1.69]O[subscript x] Cobaltite Rods by Laser Floating Zone Method | p. 203 |
Growth and Characterization of Germanium-Based Type I Clathrate Thin Films Deposited by Pulsed Laser Ablation | p. 211 |
Synthesis and Characterization of Chalcogenide Nanocomposites | p. 221 |
Anomalous Thermal Conductivity Observed in the Na[subscript 1-x]Mg[subscript x]V[subscript 2]O[subscript 5] Single Crystals | p. 227 |
Physical Properties of Hot-Pressed K[subscript 8]Ge[subscript 44 square subscript 2] | p. 233 |
Transparent Electronic Ceramics | |
Advanced Indium Tin Oxide Ceramic Sputtering Targets and Transparent Conductive Thin Films | p. 243 |
Author Index | p. 257 |
Preface | p. ix |
Introduction | p. xi |
Advanced Dielectric, Piezoelectric and Ferroelectric Materials | |
Lead Strontium Zirconate Titanate (PSZT) Thin Films for Tunable Dielectric Applications | p. 3 |
Nanosize Engineered Ferroelectric/Dielectric Single and Multilayer Films for Microwave Applications | p. 9 |
Construction and Characterization of (Y,Yb)MnO[subscript 3]/HfO[subscript 2] Stacking Layers for Application to FeRAM | p. 17 |
Temperature Dependence on the Structure and Property of Li[subscript 0.06](Na[subscript 0.5]K[subscript 0.5])[subscript 0.94]NbO[subscript 3] Piezoceramics | p. 25 |
Polar Axis Orientation and Electrical Properties of Alkoxy-Derived One Micro-Meter-Thick Ferro-/Piezoelectric Films | p. 33 |
Processing of Porous Li[subscript 0.06](Na[subscript 0.5]K[subscript 0.5])[subscript 0.94]NbO[subscript 3] Ceramics and Their Piezoelectric Composites with Hetero-Crystals | p. 43 |
Electric-Field-Induced Dielectric, Domain and Optical Phenomena in High-Strain Pb(In[subscript fraction12]Nb[subscript fraction12])[subscript 1-x]Ti[subscript x]O[subscript 3] (x=0.30) Single Crystal | p. 49 |
Effects of Electric Field on the Biaxial Strength of Poled PZT | p. 57 |
Piezoelectric Ceramic Fiber Composites for Energy Harvesting and Active Structural Control | p. 69 |
Dielectric Property of Resin-Based Composites Dispersing Ceramic Filler Particles | p. 79 |
The Effect of Sintering Conditions and Dopants on the Dielectric Loss of the Giant Dielectric Constant Perovskite CaCu[subscript 3]Ti[subscript 4]O[subscript 12] | p. 87 |
Electroceramic Materials for Sensors | |
Multifunctional Potentiometric Gas Sensor Array with an Integrated, Heater and Temperature Sensors | p. 101 |
Prussian Blue Nanoparticles Encapsulated Within Ormosil Film | p. 109 |
Gas-Sensing Property of Highly Selective NO[subscript x] Decomposition Electrochemcial Reactor | p. 125 |
The Structure, Electrical and CO-Sensing Properties of Perovskite- Type La[subscript 0.8]Pb[subscript 0.2]Fe[subscript 0.8]Cu[subscript 0.2]O[subscript 3] Ceramic | p. 133 |
NiCr[subscript 2]O[subscript 4] and NiO Planar Impedance-NO[subscript x] Sensors for High Temperature Applications | p. 141 |
Thermoelectric Materials for Power Conversion Applications | |
The Development of Thermoelectric Oxides with Perovskite-Type Structures for Alternative Energy Technologies | p. 151 |
Power Generation of p-Type Ca[subscript 3]Co[subscript 4]O[subscript 9]/n-Type CaMnO[subscript 3] Module | p. 161 |
Thermoelectric Properties of Pb and Sr Doped Ca[subscript 3]Co[subscript 4]4O[subscript 9] | p. 171 |
Thermoelectric Properties of Mix-Crystal Compound Mg[subscript 2]Si-Mg[subscript 3]Sb[subscript 2] | p. 185 |
Thermoelectric Performance of Doped SrO(SrTiO[subscript 3])n (n = 1, 2) Ruddlesden-Popper Phases | p. 193 |
Growth of Bi[subscript 2]Ca[subscript 2]Co[subscript 1.69]O[subscript x] Cobaltite Rods by Laser Floating Zone Method | p. 203 |
Growth and Characterization of Germanium-Based Type I Clathrate Thin Films Deposited by Pulsed Laser Ablation | p. 211 |
Synthesis and Characterization of Chalcogenide Nanocomposites | p. 221 |
Anomalous Thermal Conductivity Observed in the Na[subscript 1-x]Mg[subscript x]V[subscript 2]O[subscript 5] Single Crystals | p. 227 |
Physical Properties of Hot-Pressed K[subscript 8]Ge[subscript 44 square subscript 2] | p. 233 |
Transparent Electronic Ceramics | |
Advanced Indium Tin Oxide Ceramic Sputtering Targets and Transparent Conductive Thin Films | p. 243 |
Author Index | p. 257 |
Table of Contents provided by Ingram. All Rights Reserved. |
The New copy of this book will include any supplemental materials advertised. Please check the title of the book to determine if it should include any access cards, study guides, lab manuals, CDs, etc.
The Used, Rental and eBook copies of this book are not guaranteed to include any supplemental materials. Typically, only the book itself is included. This is true even if the title states it includes any access cards, study guides, lab manuals, CDs, etc.