05537nam 2200685Ia 450 991100485910332120241101104431.01-281-07730-597866110773030-08-051199-6(CKB)111086367650104(EBL)316844(OCoLC)476108415(SSID)ssj0000072565(PQKBManifestationID)11123338(PQKBTitleCode)TC0000072565(PQKBWorkID)10095516(PQKB)11589344(MiAaPQ)EBC316844(PPN)156482959(EXLCZ)9911108636765010419990623d1999 uy 0engur|||||||||||txtrdacontentcrdamediacrrdacarrierModern physical metallurgy and materials engineering science, process, applications /R.E. Smallman, R.J. BishopSixth editionBoston Butterworth-Heinemann19991 online resource (449 pages)Description based upon print version of record.0-7506-4564-4 9780750645645 Includes bibliographical references and index.Front Cover; Modern Physical Metallurgy and Materials Engineering: Science, process, applications; Copyright Page; Contents; Preface; Chapter 1. The structure and bonding of atoms; 1.1 The realm of materials science; 1.2 The free atom; 1.3 The Periodic Table; 1.4 Interatomic bonding in materials; 1.5 Bonding and energy levels; Chapter 2. Atomic arrangements in materials; 2.1 The concept of ordering; 2.2 Crystal lattices and structures; 2.3 Crystal directions and planes; 2.4 Stereographic projection; 2.5 Selected crystal structures; 2.6 Inorganic glasses; 2.7 Polymeric structuresChapter 3. Structural phases their formation and transitions; 3.1 Crystallization from the melt; 3.2 Principles and applications of phase diagrams; 3.3 Principles of alloy theory; 3.4 The mechanism of phase changes; Chapter 4. Defects in solids; 4.1 Types of imperfection; 4.2 Point defects; 4.3 Line defects; 4.4 Planar defects; 4.5 Volume defects; 4.6 Defect behaviour in some real materials; 4.7 Stability of defects; Chapter 5. The characterization of materials; 5.1 Tools of characterization; 5.2 Light microscopy; 5.3 X-ray diffraction analysis; 5.4 Analytical electron microscopy5.5 Observation of defects5.6 Specialized bombardment techniques; 5.7 Thermal analysis; Chapter 6. The physical properties of materials; 6.1 Introduction; 6.2 Density; 6.3 Thermal properties; 6.4 Diffusion; 6.5 Anelasticity and internal friction; 6.6 Ordering in alloys; 6.7 Electrical properties; 6.8 Magnetic properties; 6.9 Dielectric materials; 6.10 Optical properties; Chapter 7. Mechanical behaviour of materials; 7.1 Mechanical testing procedures; 7.2 Elastic deformation; 7.3 Plastic deformation; 7.4 Dislocation behaviour during plastic deformation; 7.5 Mechanical twinning7.6 Strengthening and hardening mechanisms7.7 Macroscopic plasticity; 7.8 Annealing; 7.9 Metallic creep; 7.10 Deformation mechanism maps; 7.11 Metallic fatigue; Chapter 8. Strengthening and toughening; 8.1 Introduction; 8.2 Strengthening of non-ferrous alloys by heat-treatment; 8.3 Strengthening of steels by; 8.4 Fracture and toughness; Chapter 9. Modern alloy developments; 9.1 Introduction; 9.2 Commercial steels; 9.3 Cast irons; 9.4 Superalloys; 9.5 Titanium alloys; 9.6 Structural intermetallic compounds; 9.7 Aluminium alloys; Chapter 10. Ceramics and glasses; 10.1 Classification of ceramics10.2 General properties of ceramics10.3 Production of ceramic powders; 10.4 Selected engineering ceramics; 10.5 Aspects of glass technology; 10.6 The time-dependency of strength in ceramics and glasses; Chapter 11. Plastics and composites; 11.1 Utilization of polymeric materials; 11.2 Behaviour of plastics during processing; 11.3 Fibre-reinforced composite materials; Chapter 12. Corrosion and surface engineering; 12.1 The engineering importance of surfaces; 12.2 Metallic corrosion; 12.3 Surface engineering; Chapter 13. Biomaterials; 13.1 Introduction; 13.2 Requirements for biomaterials13.3 Dental materialsFor many years, various editions of Smallman's Modern Physical Metallurgy have served throughout the world as a standard undergraduate textbook on metals and alloys. In 1995, it was rewritten and enlarged to encompass the related subject of materials science and engineering and appeared under the title Metals & Materials: Science, Processes, Applications offering a comprehensive amount of a much wider range of engineering materials. Coverage ranged from pure elements to superalloys, from glasses to engineering ceramics, and from everyday plastics to in situ composites, Amongst other favourablePhysical metallurgyMaterials scienceCiència dels materialslemacMetal·lúrgia físicalemacPhysical metallurgy.Materials science.Ciència dels materialsMetal·lúrgia física669/.9Smallman R. E.627326Bishop R. J(Ray J.),MiAaPQMiAaPQMiAaPQBOOK9911004859103321Modern physical metallurgy and materials engineering1213493UNINA