Oxford : , : Elsevier, , 2014

0-08-101347-7

0-08-096985-2

1 online resource (xxvli, 860 pages) : illustrations (some color)

Gale eBooks

669

Metallurgy

Inglese

Description based upon print version of record.

Includes bibliographical references and index.

Front Cover; Treatise on Process Metallurgy: Process Phenomena; Copyright; Dedication; Contents; Preface; Editor in Chief; Co-Editors-in-Chief; Contributors to Volume 2; Acknowledgement; The Review Committee; Chapter 1: Interfacial Phenomena in High Temperature Metallurgy; Chapter 1.1: Surfaces and Interfaces; 1.1.1. Definition of Surfaces and Interfaces; 1.1.2. Gibbs Adsorption Isotherm; 1.1.3. Langmuir's Isotherm; References; Chapter 1.2: Surface Tension and Contact Angle; 1.2.1. Surface Tension; 1.2.1.1. Definition of Surface Tension; 1.2.1.2. Temperature Dependence of Surface Tension

1.2.2. Contact Angle1.2.2.1. Young's Equation; 1.2.2.2. Smith's Equation; 1.2.2.3. Effect of Surface Roughness; 1.2.3. Wetting; References; Chapter 1.3: Experiments; 1.3.1. Sessile Drop; 1.3.2. Maximum Bubble Pressure; 1.3.3. Pendent Drop; 1.3.4. Drop Weight; 1.3.5. Detachment Method; 1.3.6. Liquid Surface Contour Method; 1.3.7. Capillary Rise Method; 1.3.8. Levitating Drop; Appendix A. Software for Evaluation of Surface Tension from Sessile Drop; References; Chapter 1.4: Surface Tension Models; 1.4.1. Modeling of

Surface Tension of Liquid Pure Metals and Molten Salts

1.4.2. Modeling of Surface Tension of Liquid Alloys1.4.3. Modeling of Surface Tension of Molten Ionic Materials Including Molten Slag; 1.4.3.1. Some Issues on the Evaluation of Molten Ionic Mixtures; 1.4.3.2. Evaluation of Surface Tension of Molten Ionic Mixtures; 1.4.3.3. Evaluation of Surface Tension of Molten SiO2 based Binary and Ternary Slag; 1.4.4. Evaluation of Interfacial Tension Between Liquid Steel and Molten Slag; 1.4.5. Application of Constrained Gibbs Energy Minimization Approach to Evaluate Surface Tension of Liquid Alloys

1.4.5.1. Basic Thermodynamic for Constrained Gibbs Energy Minimization Approach1.4.5.2. Use of Gibbs Energy Minimizer for Surface Equilibria Calculations; 1.4.5.3. Some Results; References; Chapter 1.5: Interfacial Free Energy and Wettability; 1.5.1. Wettability; 1.5.2. Interfacial Free Energy Between Solid and Liquid Phases in Metals and Alloys; 1.5.3. Interfacial Tension Between Liquid Steel and Molten Slag; References; Chapter 1.6: Some Aspects of Electrochemistry of Interfaces; 1.6.1. Basics of Electrochemistry of Interfaces; 1.6.1.1. Electrochemical Equilibria

1.6.1.2. Electrochemical Double Layer1.6.2. Electrocapillary Phenomena; 1.6.2.1. Electrocapillary Equation; 1.6.2.2. Adsorption and Electrocapillary Curves; 1.6.2.3. Electrocapillarity at the Slag/Metal Interface; 1.6.2.4. Some Practical Aspects of Electrocapillary Phenomena; 1.6.2.5. Wettability and Wear of Refractory Materials; 1.6.2.6. Clogging in Casting Processes; 1.6.2.7. Emulsification of Metal and Slag; 1.6.2.8. Separation Technology; References; Chapter 1.7: Interfacial Convection and Its Effect on Material Processing; 1.7.1. Some Basics of the Interfacial Convection

1.7.2. Effect of Interfacial Flow in Liquid-Liquid Reactions

Process metallurgy provides academics with the fundamentals of the manufacturing of metallic materials, from raw materials into finished parts or products.   Coverage is divided into three volumes, entitled Process Fundamentals, encompassing process fundamentals, extractive and refining processes, and metallurgical process phenomena; Processing Phenomena, encompassing ferrous processing; non-ferrous processing; and refractory, reactive and aqueous processing of metals; and Industrial Processes, encompassing process modeling and computational tools, energy optimizat