《陶瓷的表征(英文)》的主要內容包括:Preface to the Reissue of the Materials Characterization Series xi;Preface to Series xii;Preface to the Reissue of Characterization of Ceramics xiii;Preface xiv;Contributors xvii等。
基本介紹
- 書名:陶瓷的表征
- 作者:布倫德爾 (Brundle C.R.)
- 出版日期:2014年1月1日
- 語種:簡體中文, 英語
- ISBN:9787560342863
- 品牌:哈爾濱工業大學出版社
- 外文名:Ceramics
- 出版社:哈爾濱工業大學出版社
- 頁數:295頁
- 開本:16
- 定價:108.00
基本介紹,內容簡介,作者簡介,圖書目錄,文摘,
基本介紹
內容簡介
《陶瓷的表征(英文)》由哈爾濱工業大學出版社出版。
作者簡介
作者:(美國)布倫德爾(Brundle C.R.) (美國)埃文斯(Evans C.A.) (美國)列奧曼(Ronald E.Loehman)
Ronald E. Loehman,Engineers and scientists who frequently deal with ceramics are unlikely to beaware of the full range of characterization techniques applicable for findingsurface and microanalytical information on their materials. Characterization ofCeramics discusses areas of ceramics where surface and analytical information are important to processing and determination of properties. This uniquereference presents material through case histories to illustrate the applicability of different analytical techniques to ceramics. Different techniques arecompared and contrasted to give the reader sufficient basis for selecting oneover another. Each chapter begins with brief background information on thetopic, followed by a more extensive discussion of applications and benefits ofthe techniques.
Ronald E. Loehman,Engineers and scientists who frequently deal with ceramics are unlikely to beaware of the full range of characterization techniques applicable for findingsurface and microanalytical information on their materials. Characterization ofCeramics discusses areas of ceramics where surface and analytical information are important to processing and determination of properties. This uniquereference presents material through case histories to illustrate the applicability of different analytical techniques to ceramics. Different techniques arecompared and contrasted to give the reader sufficient basis for selecting oneover another. Each chapter begins with brief background information on thetopic, followed by a more extensive discussion of applications and benefits ofthe techniques.
圖書目錄
Preface to the Reissue of the Materials Characterization Series xi
Preface to Series xii
Preface to the Reissue of Characterization of Ceramics xiii
Preface xiv
Contributors xvii
POWDER AND PRECURSOR PREPARATION BY SOLUTION
TECHNIQUES
POWDER PREPARATION BY GAS—PHASE TECHNIQUES
FORMATION OF CERAMIC FILMS AND COATINGS
CONSOLIDATION OF CERAMIC THICK FILMS
CONSOLIDATION OF BULK CERAMICS
INORGANIC GLASSES AND GLASS—CERAMICS
CERAMIC MICROSTRUCTURES
CERAMIC REACTIONS AND PHASE BEHAVIOR
MECHANICAL PROPERTIES AND FRACTURE
CERAMIC COMPOSITES
GLASS AND CERAMIC JOINTS
ELECTRONIC AND MAGNETIC CERAMICS
NONDESTRUCTIVE EVALUATION
APPENDIX: TECHNIQUE SUMMARIES
Preface to Series xii
Preface to the Reissue of Characterization of Ceramics xiii
Preface xiv
Contributors xvii
POWDER AND PRECURSOR PREPARATION BY SOLUTION
TECHNIQUES
POWDER PREPARATION BY GAS—PHASE TECHNIQUES
FORMATION OF CERAMIC FILMS AND COATINGS
CONSOLIDATION OF CERAMIC THICK FILMS
CONSOLIDATION OF BULK CERAMICS
INORGANIC GLASSES AND GLASS—CERAMICS
CERAMIC MICROSTRUCTURES
CERAMIC REACTIONS AND PHASE BEHAVIOR
MECHANICAL PROPERTIES AND FRACTURE
CERAMIC COMPOSITES
GLASS AND CERAMIC JOINTS
ELECTRONIC AND MAGNETIC CERAMICS
NONDESTRUCTIVE EVALUATION
APPENDIX: TECHNIQUE SUMMARIES
文摘
著作權頁:
Controlling the partial pressure of oxygen over the reacting mixture can also havea profound effect on the rate of reaction in cases where the number of defects andeven the particular phases involved can be changed. The current interest in hightemperature superconductors provides an excellent example. Because the range ofoxygen nonstoichiometry can be relatively large in these materials, the number ofanion vacancies can vary widely. The vacancy content of the product layer, in thisexample, will determine the diffusion rates within the barrier phase and therebycontrol the rate of reaction.
The Hedvall effect was mentioned previously as another potential influence onreactivity. Since changes in rate have been noted during magnetic transitions, it mayseem reasonable to conclude that the internal magnetic field set up by the reactantsand products alters the rate of the reaction during that time. That raises the questionof whether or not the imposition of an external magnetic field will affect the courseof a reaction involving magnetic materials. Studies of this topic have——not alwaysagreed—see, for example, Reference 30 and references therein.
It is less controversial that an external electrical field will affect reactions, sincethere is frequently a flux of electrons involved in the particular overall reaction. Thenature of the electrical contacts is important in such reactions; for example, is therea dosed—circuit conduction path or is there only a field applied without contacts?Even the provision for a short circuit without the application of an external field willfacilitate many reactions. The buildup of charge barriers at interfaces such as grainboundaries becomes an important consideration in these cases.
Controlling the partial pressure of oxygen over the reacting mixture can also havea profound effect on the rate of reaction in cases where the number of defects andeven the particular phases involved can be changed. The current interest in hightemperature superconductors provides an excellent example. Because the range ofoxygen nonstoichiometry can be relatively large in these materials, the number ofanion vacancies can vary widely. The vacancy content of the product layer, in thisexample, will determine the diffusion rates within the barrier phase and therebycontrol the rate of reaction.
The Hedvall effect was mentioned previously as another potential influence onreactivity. Since changes in rate have been noted during magnetic transitions, it mayseem reasonable to conclude that the internal magnetic field set up by the reactantsand products alters the rate of the reaction during that time. That raises the questionof whether or not the imposition of an external magnetic field will affect the courseof a reaction involving magnetic materials. Studies of this topic have——not alwaysagreed—see, for example, Reference 30 and references therein.
It is less controversial that an external electrical field will affect reactions, sincethere is frequently a flux of electrons involved in the particular overall reaction. Thenature of the electrical contacts is important in such reactions; for example, is therea dosed—circuit conduction path or is there only a field applied without contacts?Even the provision for a short circuit without the application of an external field willfacilitate many reactions. The buildup of charge barriers at interfaces such as grainboundaries becomes an important consideration in these cases.
