05065nam 22006734a 450 991080991360332120230120004112.01-281-07196-X97866110719670-08-054378-2(CKB)1000000000008486(EBL)316917(OCoLC)476108831(SSID)ssj0000270481(PQKBManifestationID)11217854(PQKBTitleCode)TC0000270481(PQKBWorkID)10261605(PQKB)10886585(MiAaPQ)EBC316917(Au-PeEL)EBL316917(CaPaEBR)ebr10041467(CaONFJC)MIL107196(EXLCZ)99100000000000848619990819d1999 uy 0engur|n|---|||||txtccrWettability at high temperatures[electronic resource] /by Nicolas Eustathopoulos, Michael G. Nicholas, Béatrice Drevet1st ed.Amsterdam ;New York Pergamon19991 online resource (439 p.)Pergamon materials series ;v. 3Description based upon print version of record.0-08-042146-6 Includes bibliographical references and index.Cover; Contents; Series Preface; Preface; Chapter 1. Fundamental equations of wetting; 1.1. Surface and interfacial energies in solid/liquid/vapour systems; 1.2. Ideal solid surfaces; 1.3. Non-ideal solid surfaces; 1.4. Different types of wetting; Chapter 2. Dynamics of wetting by metals and glasses; 2.1. Non-reactive wetting; 2.2. Reactive wetting; Chapter 3. Methods of measuring wettability parameters; 3.1. Sessile drop experiments; 3.2. The wetting balance technique; 3.3. Accuracy of contact angle data; 3.4. Concluding remarks; Chapter 4. Surface energies; 4.1. Data for metals and alloys4.2. Data for non-metallic compounds4.3. Concluding remarks; Chapter 5. Wetting properties of metal/metal systems; 5.1. A pure liquid metal on its own solid; 5.2. Systems with negligible mutual solubility; 5.3. Systems with significant mutual solubility; 5.4. Effects of alloying elements; 5.5. Systems that form intermetallic compounds; 5.6. Wetting under technical conditions; 5.7. Concluding remarks; Chapter 6. Wetting properties of metal/oxide systems; 6.1. Reactive and non-reactive systems; 6.2. Non-reactive pure metal/ionocovalent oxide systems6.3. Effect of electronic structure of the oxide6.4. Effects of oxygen; 6.5. Alloying elements; 6.6. Wetting of fluorides; 6.7. Concluding remarks; Chapter 7. Wetting properties of metal/non-oxide ceramic systems; 7.1. Metals on predominantly covalent ceramics; 7.2. Metals on metal-like ceramics; Chapter 8. Wetting properties of metal/carbon systems; 8.1. Non-reactive systems; 8.2. Reactive systems; 8.3. Concluding remarks; Chapter 9. Wetting by glasses and salts; 9.1. The glassy state; 9.2. Wetting behaviour; Chapter 10. Wetting when joining; 10.1. Flow into capillary gaps10.2. Joining metal components10.3. Joining ceramic components: ceramic-ceramic and ceramic-metal joints; 10.4. Joining by related techniques; 10.5. Effects on mechanical properties; Appendix A. The Laplace equation; Appendix B. Free energy of formation of a meniscus on a vertical plate in the gravitational field; Appendix C. Contact angle hysteresis for heterogeneous solid surfaces; Appendix D. Estimation of the mass of a sessile drop needed for an optimised sLV measurement; Appendix E. Wetting balance: the case of cylindrical solidsAppendix F. Surface energies of cubic diamond structure compoundsAppendix G. Enthalpy of mixing of binary liquid alloys; Appendix H. Secondary wetting; Appendix I. Evaluation of the work of adhesion of Ni on SiC; List of symbols; Selective Index; AcknowledgementsThe purpose of this book is to bring together current scientific understanding of wetting behaviour that has been gained from theoretical models and quantitative experimental observations. The materials considered are liquid metals or inorganic glasses in contact with solid metals or ceramics at temperatures of 200-2000oC. Wetting has been a significant scientific concern for the last two centuries and reference will be made to classical work by nineteenth century scientists such as Dupré, Laplace and Young that was validated by observations of the behaviour of chemically inertPergamon materials series ;v. 3.WettingMaterials at high temperaturesWetting.Materials at high temperatures.541.3/3Eustathopoulos Nicolas1720377Nicholas Michael G1720378Drevet Béatrice1720379MiAaPQMiAaPQMiAaPQBOOK9910809913603321Wettability at high temperatures4118976UNINA