07498nam 2200697Ia 450 991045139290332120200520144314.0981-277-016-X(CKB)1000000000411541(EBL)1193472(SSID)ssj0000221832(PQKBManifestationID)11235393(PQKBTitleCode)TC0000221832(PQKBWorkID)10162597(PQKB)11655828(MiAaPQ)EBC1193472(WSP)00006519(Au-PeEL)EBL1193472(CaPaEBR)ebr10255853(CaONFJC)MIL491685(OCoLC)646768833(EXLCZ)99100000000041154120080324d2007 uy 0engur|n|---|||||txtccrPiezoelectricity, acoustic waves and device applications[electronic resource] proceedings of the 2006 Symposium, Zhejiang University, China, 14-16, December 2006 /editors, Ji Wang, Weiqiu ChenHackensack, N.J. World Scientificc20071 online resource (400 p.)Text in English and Chinese.981-270-813-8 Includes bibliographical references and author index.ORGANIZERS AND COMMITTEES; FOREWORD; CONTENTS; Piezoelectricity; Acoustic Waves and Vibrations; Device Applications; 声电转换材料的研究进展; 1. 引言; 2. 声电材料的研究现状及分类; 2.1. 压电材料的分类; 2.1.1. 压电陶瓷; 2.1.3. 压电半导体; 2.1.4. 压电高聚物; 2.1.5. 压电复合材料; 2.2. 压磁材料的分类; 2.2.1. 铁磁金属类; 2.2.2. 铁氧体; 2.2.3 稀土超磁致伸缩材料; 3. 压电与压磁材料的性能改进; 3.1. 压电材料(PZT)的性能改进; 3.1.1. 压电陶瓷制备方法的改进; 3.1.2. 压电陶瓷的掺杂改性; 3.2. 压磁材料的性能改进; 3.2.1. 稀土超磁致伸缩材料的制备方法的改进; 3.2.2. 稀土超磁致伸缩材料的掺杂改性; 4. 声电转换材料的应用; 5. 结论; 无铅压电陶瓷材料的研究; 1. 压电陶瓷及压电效应; 1.1. 压电陶瓷及其分类; 1.2. 压电效应; 1.3. 压电陶瓷材料的应用; 2. 开发无铅压电陶瓷材料的研究与发展; 2.1. 新型无铅压电陶瓷研究; 2.1.1. NaNbO3 的研究; 2.1.2. Bi 层状结构化合物2.1.3. 以碱性金属铌酸盐为基的陶瓷体系2.1.4. 以钛酸铋钠为基的二元或多元陶瓷体系; 2.2. 无铅压电陶瓷的晶格缺陷对压电性的影响; 2.3. 无铅压电陶瓷对电子发射性能的影响; 3. 结束语; 超细粉体技术的发展现状及其应用; 1. 前言; 1.1. 小尺寸效应; 1.2. 表面与界面效应; 1.3. 量子尺寸效应; 2. 超细粉体科学与技术; 2.1. 超细粉体的制备方法; 2.2 超细粉体的分级技术; 2.3. 超细粉体的表面改性与修饰; 3. 超细粉体技术的应用领域; 3.1. 超细粉体在材料领域的应用; 3.2. 超细粉体技术在化工领域的应用; 3.3. 超细粉体在医药、生物及基因工程等领域的应用; 3.4. 超细粒子在新型高灵敏度传感器制造方面的应用; 3.5. 超细粉体技术在保健、日用品等领域的应用; 3.6. 超细粉体技术及产品在军事,航空,航天领域的应用; 4. 结束语; 压电高聚物的研究及应用; 1. 前言; 2. 压电效应及压电材料; 3. 压电高聚物的发现及特性; 3.1. 压电高聚物的发现; 3.2. 压电高聚物的特性; 4. 压电高聚物的种类、应用及制备; 4.1. 聚偏氟乙烯(PVDF); 4.2. 尼龙11(nylon11); 4.3. 压电橡胶(piezoelectric rubber)4.4. 压电复合材料(piezoelectric composites)5. 展望前景与总结; SUBSONIC SLIP PULSE ALONG A FRICTIONLESS INTERFACE BETWEEN TWO PIEZOELECTRIC SOLIDS IN SLIDING CONTACT WITH LOCAL SEPARATION; 1. Introduction; 2. Problem Formulation; 3. Dual Integral Equations; 4. Singular Integral Equation and Its Solution; 5. Numerical Results and Discussion; 6. Conclusions; Acknowledgments; References; 柔性压电梁结构运动稳定性分析; 1. 引言; 2. 运动方程; 3. 运动稳定性分析; 4. 算例和讨论; EFFECT OF INITIAL STRESSES ON DISPERSION RELATION FOR TRANSVERSE PIEZOELECTRIC WAVES ON A LAYERED CYLINDER; 1. Introduction; 2. General Equations3. Formulation of the Problem3.1. Governing equations for the core; 3.2. Governing the equations for the overlay; 3.3. Boundary conditions; 4. Solution of the Problem (Dispersion Relation); 5. Numerical Results and Discussion; References; A SIMPLY SUPPORTED CIRCULAR PIEZOTHERMOELASTIC PLATE UNDER UNIFORM LOADING; 1. Introduction; 2. General Solution For Piezothermoelasyic Materials; 3. Final Manuscript; 4. Numerical Results; 5. Conclusions; Acknowledgments; References; 实验研究1-3 型压电复合材料结构参数对其性能的影响; 1. 引言; 2. 1-3 系压电复合材料的制备; 3. 1-3 复合材料性能与陶瓷体积百分比的关系; 3.1. 压电常数d33 和相对介电常数33 0 ε ε 与陶瓷体积百分比的关系3.2. 厚度机电耦合系数和频率常数随陶瓷体积比变化4. 实验研究1-3 复合材料结构尺寸对厚度振动的影响; 4.1. 复合材料厚度振动频率常数的实验研究; 4.2 复合材料厚度振动与其它振动耦合的实验研究; 5. 结论; References; 节式压电梁的电阻模拟和实验研究; 1. 引言; 2. 并联式双压电晶片夹层梁的阻抗矩阵; 3. 节式压电梁的电阻抗; 4. 节式压电梁的电阻抗实验和讨论; 5. 压电片相关参数对电阻抗的影响; 6. 结论; CEO2 掺杂PB0.99CA0.006NB1.98TI0.01O5.986 高居里温度压电陶瓷的研究; 1. 引言; 2. 实验; 3. 结果分析与讨论; 3.1. X 射线衍射分析; 3.2 陶瓷的介电性能; 3.3 陶瓷的压电性能; 4. 结论; References; THE BENDING SOLUTION OF PIEZOELECTRIC FUNCTIONALLY GRADIENT RECTANGULAR THIN PLATE; 1. Introduction; 2. Statements and Basic Equation; 2.1. The mathematic model of parameter; 2.2. The government equations; 3. Solution; 3.1. Case 13.2. Case 2This volume covers important subjects in the field of piezoelectric devices and applications with the latest research on piezoelectricity, acoustic waves, manufacturing technology, and design techniques. It includes up-to-date research and information on materials, new products, technological trends, and design methods of benefit to academics and researchers in the piezoelectric device industry. Contributors to this volume include prominent experts such as Clemens Ruppel of Epcos, Daining Fang of Tsinghua University, Tong-Yi Zhang of University of Science and Technology, Hong Kong, and CS Lam Acoustic surface wavesCongressesPiezoelectric devicesCongressesPiezoelectric materialsCongressesPiezoelectricityCongressesElectronic books.Acoustic surface wavesPiezoelectric devicesPiezoelectric materialsPiezoelectricity537/.2446Chen Weiqiu978424Wang Ji978425Symposium on Piezoelectricity, Acoustic Waves and Device ApplicationsMiAaPQMiAaPQMiAaPQBOOK9910451392903321Piezoelectricity, acoustic waves and device applications2229741UNINA