![Cover image for Electroceramic materials and applications Cover image for Electroceramic materials and applications](/client/assets/5.0.0/ctx//client/images/no_image.png)
Available:*
Library | Item Barcode | Call Number | Material Type | Item Category 1 | Status |
---|---|---|---|---|---|
Searching... | 30000010113659 | TA455.C43 E43 2006 | Open Access Book | Book | Searching... |
On Order
Summary
Summary
Provides a state-of-the-art collection of recent papers on electroceramic materials as presented at the 6th PAC RIM Conference.
Author Notes
Dr. Robert Schwartz is a Professor of Materials Science & Engineering and Associate Chair for Graduate Programs at the University of Missouri - Rolla. Dr. Schwartz conducts research on piezoelectric composites, dielectric materials, and the chemical synthesis of electronic materials. Dr. Schwartz was previously employed as Associate and Assistant Professor of Materials Science & Engineering at Clemson University from 1997 through 2002, as a Senior Member of the Technical Staff at Sandia National Laboratories from 1989 through 1997, and as a Research Engineer at BFGoodrich from 1980 through 1984. Dr. Schwartz received his B.S. degree in science education and his M.S. degree in chemistry, both from North Carolina State University. He received his Ph.D. in ceramic engineering from the University of Illinois, Urbana, Illinois, in 1989. Dr. Schwartz is the holder of two patents, has published approximately 90 papers, and has written five book chapters.
Table of Contents
Preface | p. xi |
High Temperature Superconductors: Processing and Properties | |
Effect of Initial Phases in Precursor on the Formation and Properties of Bi2223 Sheathed With Ag-Cu Alloy | p. 3 |
Thickness Dependence of Critical Current Density in IBAD/PLD YBCO Coated Conductor | p. 13 |
Drastically Innovative BSCCO Long Length Wire by Controlled Over Pressure Sintering | p. 23 |
Single Grain YBa[subscript 2]Cu[subscript 3]O[subscript y] Porous Ceramic Superconductors | p. 33 |
Benefits of Using a Nanostructured Target in Laser Ablation of Thin YBCO Films | p. 45 |
Impurity-Doping Effects on Critical Current Properties in ErBa[subscript 2]Cu[subscript 3]O[subscript y] Films | p. 57 |
Synthesis of a New Copper Oxide "In[subscript 0.3]Cu[subscript 0.7]Ba[subscript 2]LaCu[subscript 2]O[subscript y]" and Characterization of its Physical Properties | p. 67 |
Micro-Coulometry for Measuring Oxygen Content in Copper Oxides | p. 77 |
Iodine Intercalation and Deintercalation of a Sr-Free Bi-Based Cuprate: Bi[subscript 2](La,Na)[subscript 2]CuO[subscript z] | p. 85 |
Dielectric, Ferroelectric, Piezoelectric and Electrooptic Materials | |
Progress in Ferroelectric Domain Engineering at the Micro/Nanoscale | p. 93 |
Domain Wall Engineering in Lead-Free Piezoelectric Materials for Enhanced Piezoelectric Properties | p. 109 |
Observations of 180[Degree] Ferroelectric Domains through Lithium Niobate Using Bragg and Laue X-Ray Topography with the Application of Electric Fields | p. 119 |
Domain Engineering Ferroelectric Crystals for Nonlinear Optics | p. 127 |
Role of Extrinsic Defects in Ferroelectric Domain Inversion of Lithium Niobate | p. 143 |
Effects of Excess Bismuth Addition on Ferroelectric Properties and Memory Characteristics of Bi[subscript 3.25]Lac[subscript 0.75]Ti[subscript 3]O[subscript 12] Thin Films Fabricated by Sputtering | p. 155 |
Scanning Probe Methods for Characterization of Electrical Properties in Nano-Materials | p. 163 |
Dielectric Permittivity Mapping With Non-Contact Microwave Probe for Dielectric Materials | p. 175 |
Dielectric Anomaly in Perovskite Artificial Superlattices | p. 185 |
Effects of Bismuth Deficiency on Piezoelectric Properties of (Bi[subscript 0.5-x]Na[subscript 0.5]TiO[subscript 3])[subscript 0.94](BaTiO[subscript 3])[subscript 0.06] Ceramics | p. 193 |
Electrical Property Improvement of CaBi[subscript 4]Ti[subscript 4]O[subscript 15] Ceramics by Doping and Grain Orientation | p. 203 |
Electrical Properties of BaBi[subscript 4]Ti[subscript 4]O[subscript 15] Ceramics Modified by Bi[subscript 2]SiO[subscript 5] | p. 217 |
Preparation and Characterization of Lead-Free Piezoelectric (K[subscript 0.5]Bi[subscript 0.5])TiO[subscript 3] Ceramics | p. 227 |
Ultra-Wide Bandwidth, Thin Film Electro-Optic Modulators | p. 237 |
Refined Position of the Morphotropic Phase Boundary for Pb(Mg[subscript 1/3]Nb[subscript 2/3]O[subscript 3]-PbZrO[subscript 3]-PbTiO[subscript 3] Ceramics | p. 243 |
Thermoelectric and Energy Harvesting Materials for Solid State Power Conversion | |
Fabrication of Grain-Aligned Thick Films of Thermoelectric Oxides by an Electrophoretic Deposition Method under High Magnetic Fields | p. 257 |
Microstructure Studies of Ca[subscript 3]Co[subscript 4]O[subscript 9] Thin Films on Glass Substrates | p. 267 |
Improving Thermoelectric Device Performance and Durability through the Integration of Advanced, Aerogel-Based Ceramics | p. 275 |
Control of Magnetic Anisotropy in (Bi[subscript 1-x]Pb[subscript x])[subscript 2](AE[subscript 1-y]RE[subscript y])[subscript 2]Co[subscript 2]O[subscript 2] and Fabrication of Magnetically Aligned Bulks | p. 291 |
High-Quality Epitaxial Film Growth of Superconducting Sodium-Cobalt Oxyhydrate, Na[subscript 0.3]CoO[subscript 2 middot]1.3H[subscript 2]O | p. 303 |
Effect of Grain Size of Precursor Powder on Thermoelectric Properties of Textured Ca[subscript 3]Co[subscript 4]O[subscript 9] Compounds | p. 311 |
Investigation of Thermoelectric Properties of Metallic Na[subscript x]Co[subscript 2]O[subscript 4] Materials | p. 323 |
Preparation and Thermoelectric Properties of Highly Oriented Na[subscript 1.5]Co[subscript 2]O[subscript 4] and Ca[subscript 3]Co[subscript 40]9 Ceramics by the Spark Plasma Sintering Method | p. 333 |
High-Temperature Thermoelectric Performance of Strontium Titanate Degenerate Semiconductors | p. 343 |
Preparation and Ahisotropic Thermoelectric Properties in Layered Cobaltite Thin Films | p. 349 |
Chemical Methods of Preparation of Electroceramics | |
Impact of Solution Chemistry on Successfully Depositing Sol-Gel PZT Films Directly on Copper Surfaces | p. 361 |
Sol-Gel Routes to Nanostructured Patterned Ferroelectric Thin Films With Novel Electronic and Optical Functions | p. 371 |
Patterning of Ceramics-Site-Selective Deposition of Ceramic Thin Films Using Self-Assembled Monolayers | p. 381 |
Electrical Properties of Pt/(Y,Yb)MnO[subscript 3]/HfO[subscript 2]/Si Structure Constructed Through Chemical Solution Process | p. 399 |
Controlling of Surface and Humidity Detecting Properties of Potassium Tantalate Films Fabricated by a Hydrothermal Electrochemical Method | p. 407 |
Preparation of Preferentially Oriented BaTiO[subscript 3] Thin Film by Hydrothermal Soft Chemical Process | p. 415 |
Synthesis and Characterization of Organic-Inorganic Hybrid Layer Photocatalysts | p. 423 |
Effects of pH Control on Preparation of Z-Type Hexagonal Ferrite Ba[subscript 3]Co[subscript 2]Fe[subscript 24]O[subscript 41] by Polymerized Complex Method | p. 435 |
Effect of Pyrolysis Temperatures on ZnO Films on Soda-Lime-Silica Glass Substrates Prepared by Chemical Solution Deposition | p. 441 |
Effect of Ba Substitution on Structure and Electrical Properties of SrRuO[subscript 3] | p. 449 |
Alkoxy-Derived Photochromic ZrO[subscript 2] Precursor | p. 457 |
Fundamental Properties of Conducting and Magnetic Electroceramics | |
Transparent Conducting Properties in Layered Oxychalcogenides | p. 467 |
ZnO:Ga-Based Transparent Conductive Films: An Attractive Potential For Use in Flat Panel Display | p. 475 |
Coloration and Bleaching Phenomena of Amorphous WO[subscript 3] Films Due to the Electrochemical Insertion of Divalent Cations | p. 491 |
Preparation of Z-Type Hexagonal Ferrite, Co[subscript 2]Z, Using Alkaline Halide Method | p. 497 |
Preparation and Characterization of FeTiO[subscript 3]-Fe[subscript 2]O[subscript 3] Solid Solution System | p. 505 |
Oxygen-Relaxation of ZR[subscript 1-X]Y[subscript X]O[subscript 2-X/2] (X = 0.04, 0.08, and 0.15) Ceramics Observed by Internal Friction Measurement | p. 513 |
Study on Nonvolatile Memory Based on Electric-Pulse-Induced Reversible Resistance Change Effect | p. 519 |
Author Index | p. 527 |