ABUASSOLA مهندس تحت الاختبار
عدد المساهمات : 23 التقييم : 67 تاريخ التسجيل : 13/12/2012 العمر : 46 الدولة : السودان العمل : محاضر الجامعة : جامعة وادي النيل
| موضوع: كتاب Fundamentals of Materials Science and Engineering - An Integrated Approach الأحد 26 يناير 2014, 10:29 pm | |
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أخوانى فى الله أحضرت لكم كتاب Fundamentals of Materials Science and Engineering An Integrated Approach William D. Callister, Jr. Department of Metallurgical Engineering The University of Utah David G. Rethwisch Department of Chemical and Biochemical Engineering The University of Iowa
و المحتوى كما يلي :
Contents List of Symbols Xxiii . Introduction Learning Objectives . Historical Perspective . Materials Science and Engineering . Why Study Materials Science and Engineering? Case Study—Liberty Ship Failures . Classification of Materials Case Study—Carbonated Beverage Containers . Advanced Materials . Modern Materials’ Needs Summary References Questions . Atomic Structure and Interatomic Bonding Learning Objectives . Introduction ATOMIC STRUCTURE . Fundamental Concepts . Electrons in Atoms . The Periodic Table ATOMIC BONDING IN SOLIDS . Bonding Forces and Energies . Primary Interatomic Bonds . Secondary Bonding or van der Waals Bonding Materials of Importance—Water (Its Volume Expansion upon Freezing) . Mixed Bonding . Molecules . Bonding Type-Material Classification Correlations Summary Equation Summary List of Symbols Important Terms and Concepts References Questions and Problems Fundamentals of Engineering Questions and Problems . Structures of Metals and Ceramics Learning Objectives . Introduction CRYSTAL STRUCTURES . Fundamental Concepts . Unit Cells . Metallic Crystal Structures . Density Computations—Metals . Ceramic Crystal Structures . Density Computations—Ceramics . Silicate Ceramics . Carbon . Polymorphism and Allotropy . Crystal Systems Material of Importance—Tin (Its Allotropic Transformation) CRYSTALLOGRAPHIC POINTS, DIRECTIONS, AND PLANES . Point Coordinates . Crystallographic Directions . Crystallographic Planes . Linear and Planar Densities . Close-Packed Crystal Structures CRYSTALLINE AND NONCRYSTALLINE MATERIALS . Single Crystals . Polycrystalline Materials . Anisotropy . X-Ray Diffraction: Determination of Crystal Structures . Noncrystalline Solids Summary Equation Summary List of Symbols Important Terms and Concepts References xvi • Contents Questions and Problems Fundamentals of Engineering Questions and Problems . Polymer Structures Learning Objectives . Introduction . Hydrocarbon Molecules . Polymer Molecules . The Chemistry of Polymer Molecules . Molecular Weight . Molecular Shape . Molecular Structure . Molecular Configurations . Thermoplastic and Thermosetting Polymers . Copolymers . Polymer Crystallinity . Polymer Crystals Summary Equation Summary List of Symbols Important Terms and Concepts References Questions and Problems Fundamentals of Engineering Questions and Problems . Imperfections in Solids Learning Objectives . Introduction POINT DEFECTS . Point Defects in Metals . Point Defects in Ceramics . Impurities in Solids . Point Defects in Polymers . Specification of Composition MISCELLANEOUS IMPERFECTIONS . Dislocations—Linear Defects . Interfacial Defects . Bulk or Volume Defects . Atomic Vibrations Materials of Importance—Catalysts (and Surface Defects) MICROSCOPIC EXAMINATION . Basic Concepts of Microscopy . Microscopic Techniques . Grain-Size Determination Summary Equation Summary List of Symbols Important Terms and Concepts References Questions and Problems Design Problems Fundamentals of Engineering Questions and Problems . Diffusion Learning Objectives . Introduction . Diffusion Mechanisms . Fick’s First Law . Fick’s Second Law—Nonsteady-State Diffusion . Factors that Influence Diffusion . Diffusion in Semiconducting Materials Materials of Importance—Aluminum for Integrated Circuit Interconnects . Other Diffusion Paths . Diffusion in Ionic and Polymeric Materials Summary Equation Summary List of Symbols Important Terms and Concepts References Questions and Problems Design Problems Fundamentals of Engineering Questions and Problems . Mechanical Properties Learning Objectives . Introduction . Concepts of Stress and Strain ELASTIC DEFORMATION . Stress–Strain Behavior . Anelasticity . Elastic Properties of Materials MECHANICAL BEHAVIOR—METALS . Tensile Properties . True Stress and Strain . Elastic Recovery after Plastic Deformation . Compressive, Shear, and Torsional Deformations MECHANICAL BEHAVIOR—CERAMICS . Flexural Strength Contents • xvii . Elastic Behavior . Influence of Porosity on the Mechanical Properties of Ceramics MECHANICAL BEHAVIOR—POLYMERS . Stress–Strain Behavior . Macroscopic Deformation . Viscoelastic Deformation HARDNESS AND OTHER MECHANICAL PROPERTY CONSIDERATIONS . Hardness . Hardness of Ceramic Materials . Tear Strength and Hardness of Polymers PROPERTY VARIABILITY AND DESIGN/SAFETY FACTORS . Variability of Material Properties . Design/Safety Factors Summary Equation Summary List of Symbols Important Terms and Concepts References Questions and Problems Design Problems Fundamentals of Engineering Questions and Problems . Deformation and Strengthening Mechanisms Learning Objectives . Introduction DEFORMATION MECHANISMS FOR METALS . Historical . Basic Concepts of Dislocations . Characteristics of Dislocations . Slip Systems . Slip in Single Crystals . Plastic Deformation of Polycrystalline Metals . Deformation by Twinning MECHANISMS OF STRENGTHENING IN METALS . Strengthening by Grain Size Reduction . Solid-Solution Strengthening . Strain Hardening RECOVERY, RECRYSTALLIZATION, AND GRAIN GROWTH . Recovery . Recrystallization . Grain Growth DEFORMATION MECHANISMS FOR CERAMIC MATERIALS . Crystalline Ceramics . Noncrystalline Ceramics MECHANISMS OF DEFORMATION AND FOR STRENGTHENING OF POLYMERS . Deformation of Semicrystalline Polymers . Factors that Influence the Mechanical Properties of Semicrystalline Polymers Materials of Importance—Shrink-Wrap Polymer Films . Deformation of Elastomers Summary Equation Summary List of Symbols Important Terms and Concepts References Questions and Problems Design Problems Fundamentals of Engineering Questions and Problems . Failure Learning Objectives . Introduction FRACTURE . Fundamentals of Fracture . Ductile Fracture . Brittle Fracture . Principles of Fracture Mechanics . Brittle Fracture of Ceramics . Fracture of Polymers . Fracture Toughness Testing FATIGUE . Cyclic Stresses . The S–N Curve . Fatigue in Polymeric Materials . Crack Initiation and Propagation . Factors that Affect Fatigue Life . Environmental Effects CREEP . Generalized Creep Behavior . Stress and Temperature Effects . Data Extrapolation Methods . Alloys for High-Temperature Use xviii • Contents . Creep in Ceramic and Polymeric Materials Summary Equation Summary List of Symbols Important Terms and Concepts References Questions and Problems Design Problems Fundamentals of Engineering Questions and Problems . Phase Diagrams Learning Objectives . Introduction DEFINITIONS AND BASIC CONCEPTS . Solubility Limit . Phases . Microstructure . Phase Equilibria . One-Component (or Unary) Phase Diagrams BINARY PHASE DIAGRAMS . Binary Isomorphous Systems . Interpretation of Phase Diagrams . Development of Microstructure in Isomorphous Alloys . Mechanical Properties of Isomorphous Alloys . Binary Eutectic Systems . Development of Microstructure in Eutectic Alloys Materials of Importance—Lead-Free Solders . Equilibrium Diagrams Having Intermediate Phases or Compounds . Eutectoid and Peritectic Reactions . Congruent Phase Transformations . Ceramic Phase Diagrams . Ternary Phase Diagrams . The Gibbs Phase Rule THE IRON–CARBON SYSTEM . The Iron–Iron Carbide (Fe–Fe C) Phase Diagram . Development of Microstructure in Iron– Carbon Alloys . The Influence of Other Alloying Elements Summary Equation Summary List of Symbols Important Terms and Concepts References Questions and Problems Fundamentals of Engineering Questions and Problems . Phase Transformations Learning Objectives . Introduction PHASE TRANSFORMATIONS IN METALS . Basic Concepts . The Kinetics of Phase Transformations . Metastable Versus Equilibrium States MICROSTRUCTURAL AND PROPERTY CHANGES IN IRON–CARBON ALLOYS . Isothermal Transformation Diagrams . Continuous-Cooling Transformation Diagrams . Mechanical Behavior of Iron–Carbon Alloys . Tempered Martensite . Review of Phase Transformations and Mechanical Properties for Iron–Carbon Alloys Materials of Importance—Shape-Memory Alloys PRECIPITATION HARDENING . Heat Treatments . Mechanism of Hardening . Miscellaneous Considerations CRYSTALLIZATION, MELTING, AND GLASS TRANSITION PHENOMENA IN POLYMERS . Crystallization . Melting . The Glass Transition . Melting and Glass Transition Temperatures . Factors that Influence Melting and Glass Transition Temperatures Summary Equation Summary List of Symbols Important Terms and Concepts References Questions and Problems Design Problems Fundamentals of Engineering Questions and Problems Contents • xix . Electrical Properties Learning Objectives . Introduction ELECTRICAL CONDUCTION . Ohm’s Law . Electrical Conductivity . Electronic and Ionic Conduction . Energy Band Structures in Solids . Conduction in Terms of Band and Atomic Bonding Models . Electron Mobility . Electrical Resistivity of Metals . Electrical Characteristics of Commercial Alloys Materials of Importance—Aluminum Electrical Wires SEMICONDUCTIVITY . Intrinsic Semiconduction . Extrinsic Semiconduction . The Temperature Dependence of Carrier Concentration . Factors that Affect Carrier Mobility . The Hall Effect . Semiconductor Devices ELECTRICAL CONDUCTION IN IONIC CERAMICS AND IN POLYMERS . Conduction in Ionic Materials . Electrical Properties of Polymers DIELECTRIC BEHAVIOR . Capacitance . Field Vectors and Polarization . Types of Polarization . Frequency Dependence of the Dielectric Constant . Dielectric Strength . Dielectric Materials OTHER ELECTRICAL CHARACTERISTICS OF MATERIALS . Ferroelectricity . Piezoelectricity Material of Importance—Piezoelectric Ceramic Ink-Jet Printer Heads Summary Equation Summary List of Symbols Important Terms and Concepts References Questions and Problems Design Problems Fundamentals of Engineering Questions and Problems . Types and Applications of Materials Learning Objectives . Introduction TYPES OF METAL ALLOYS . Ferrous Alloys . Nonferrous Alloys Materials of Importance—Metal Alloys Used for Euro Coins TYPES OF CERAMICS . Glasses . Glass-Ceramics . Clay Products . Refractories . Abrasives . Cements . Carbons . Advanced Ceramics TYPES OF POLYMERS . Plastics Materials of Importance—Phenolic Billiard Balls . Elastomers . Fibers . Miscellaneous Applications . Advanced Polymeric Materials Summary Important Terms and Concepts References Questions and Problems Design Questions Fundamentals of Engineering Questions . Synthesis, Fabrication, and Processing of Materials Learning Objectives . Introduction FABRICATION OF METALS . Forming Operations . Casting . Miscellaneous Techniques THERMAL PROCESSING OF METALS . Annealing Processes . Heat Treatment of Steels xx • Contents FABRICATION OF CERAMIC MATERIALS . Fabrication and Processing of Glasses and Glass-Ceramics . Fabrication and Processing of Clay Products . Powder Pressing . Tape Casting SYNTHESIS AND FABRICATION OF POLYMERS . Polymerization . Polymer Additives . Forming Techniques for Plastics . Fabrication of Elastomers . Fabrication of Fibers and Films Summary Important Terms and Concepts References Questions and Problems Design Problems Fundamentals of Engineering Questions and Problems . Composites Learning Objectives . Introduction PARTICLE-REINFORCED COMPOSITES . Large–Particle Composites . Dispersion-Strengthened Composites FIBER-REINFORCED COMPOSITES . Influence of Fiber Length . Influence of Fiber Orientation and Concentration . The Fiber Phase . The Matrix Phase . Polymer-Matrix Composites . Metal-Matrix Composites . Ceramic-Matrix Composites . Carbon–Carbon Composites . Hybrid Composites . Processing of Fiber-Reinforced Composites STRUCTURAL COMPOSITES . Laminar Composites . Sandwich Panels Case Study—Use of Composites in the Boeing Dreamliner . Nanocomposites Summary Equation Summary List of Symbols Important Terms and Concepts References Questions and Problems Design Problems Fundamentals of Engineering Questions and Problems . Corrosion and Degradation of Materials Learning Objectives . Introduction CORROSION OF METALS . Electrochemical Considerations . Corrosion Rates . Prediction of Corrosion Rates . Passivity . Environmental Effects . Forms of Corrosion . Corrosion Environments . Corrosion Prevention . Oxidation CORROSION OF CERAMIC MATERIALS DEGRADATION OF POLYMERS . Swelling and Dissolution . Bond Rupture . Weathering Summary Equation Summary List of Symbols Important Terms and Concepts References Questions and Problems Design Problems Fundamentals of Engineering Questions and Problems . Thermal Properties Learning Objectives . Introduction . Heat Capacity . Thermal Expansion Materials of Importance—Invar and Other Low-Expansion Alloys . Thermal Conductivity . Thermal Stresses Summary Equation Summary List of Symbols Important Terms and Concepts References Questions and Problems Design Problems Contents • xxi Fundamentals of Engineering Questions and Problems . Magnetic Properties Learning Objectives . Introduction . Basic Concepts . Diamagnetism and Paramagnetism . Ferromagnetism . Antiferromagnetism and Ferrimagnetism . The Influence of Temperature on Magnetic Behavior . Domains and Hysteresis . Magnetic Anisotropy . Soft Magnetic Materials Materials of Importance—An Iron–Silicon Alloy that Is Used in Transformer Cores . Hard Magnetic Materials . Magnetic Storage . Superconductivity Summary Equation Summary List of Symbols Important Terms and Concepts References Questions and Problems Design Problems Fundamentals of Engineering Questions and Problems . Optical Properties Learning Objectives . Introduction BASIC CONCEPTS . Electromagnetic Radiation . Light Interactions with Solids . Atomic and Electronic Interactions OPTICAL PROPERTIES OF METALS OPTICAL PROPERTIES OF NONMETALS . Refraction . Reflection . Absorption . Transmission . Color . Opacity and Translucency in Insulators APPLICATIONS OF OPTICAL PHENOMENA . Luminescence . Photoconductivity Materials of Importance—Light-Emitting Diodes . Lasers . Optical Fibers in Communications Summary Equation Summary List of Symbols Important Terms and Concepts References Questions and Problems Design Problem Fundamentals of Engineering Questions and Problems . Economic, Environmental, and Societal Issues in Materials Science and Engineering Learning Objectives . Introduction ECONOMIC CONSIDERATIONS . Component Design . Materials . Manufacturing Techniques ENVIRONMENTAL AND SOCIETAL CONSIDERATIONS . Recycling Issues in Materials Science and Engineering Materials of Importance—Biodegradable and Biorenewable Polymers/ Plastics Summary References Design Questions Appendix A The International System of Units (SI) Appendix B Properties of Selected Engineering Materials B. : Density B. : Modulus of Elasticity B. : Poisson’s Ratio B. : Strength and Ductility B. : Plane Strain Fracture Toughness B. : Linear Coefficient of Thermal Expansion B. : Thermal Conductivity B. : Specific Heat B. : Electrical Resistivity B. : Metal Alloy Compositions xxii • Contents Appendix C Costs and Relative Costs for Selected Engineering Materials Appendix D Repeat Unit Structures for Common Polymers Appendix E Glass Transition and Melting Temperatures for Common Polymeric Materials Glossary Answers to Selected Problems Index Mechanical Engineering Online Module Learning Objectives M. Introduction FRACTURE M. Principles of Fracture Mechanics M. Flaw Detection Using Nondestructive Testing Techniques M. Fracture Toughness Testing FATIGUE M. Crack Initiation and Propagation M. Crack Propagation Rate AUTOMOBILE VALVE SPRING (CASE STUDY) M. Mechanics of Spring Deformation M. Valve Spring Design and Material Requirements FAILURE OF AN AUTOMOBILE REAR AXLE (CASE STUDY) M. Introduction M. Testing Procedure and Results M. Discussion MATERIALS SELECTION FOR A TORSIONALLY STRESSED CYLINDRICAL SHAFT (CASE STUDY) M. Strength Considerations—Torsionally Stressed Shaft M. Other Property Considerations and the Final Decision Summary Equation Summary Important Terms and Concepts References Questions and Problems Design Problems Glossary Answers to Selected Problems Index (Module) Library of Case Studies Case Study CS —Materials Selection for a Torsionally Stressed Cylindrical Shaft Case Study CS —Automobile Valve Spring Case Study CS —Failure of an Automobile Rear Axle Case Study CS —Artificial Total Hip Replacement Case Study CS —Intraocular Lens Implants Case Study CS —Chemical Protective ClothingContents Index Page numbers in italics refer to the glossary.Index • Angle computation between two crystallographic directions, Angle-ply, laminar composite, Anions, , Anisotropy, – , of elastic modulus, , magnetic, – Annealing, , – , ferrous alloys, – glass, Annealing point, glass, , Annealing twins, Anodes, , area effect, galvanic corrosion, sacrificial, , Antiferromagnetism, , temperature dependence, Aramid: cost as a fiber, fiber-reinforced polymer-matrix composites, – melting and glass transition temperatures, properties as fiber, repeat unit structure, , Argon, bonding energy and melting temperature, Argon-ion lasers, Aromatic hydrocarbons (chain groups), , Arrhenius equation, Artifi cial aging, , Asphaltic concrete, ASTM standards, Atactic configuration, , Athermal transformation, , Atomic bonding, see Bonding Atomic mass, Atomic mass unit (amu), , Atomic models: Bohr, , , wave-mechanical, – , Atomic number, , Atomic packing factor, , Atomic point defects, – , – Atomic radii, of selected metals, Atomic structure, – Atomic vibrations, , , Atomic weight, , metal alloys, equations for, Atom percent, , Austenite, , shape-memory phase transformations, – transformations, – summary, – Austenitic stainless steels, , Austenitizing, , Automobiles, rusted and stainless steel, Automobile transmission, Auxetic materials, Average value, Avogadro’s number, Avrami equation, , AX crystal structures, – A mXp crystal structures, Azimuthal quantum number, B Bainite, – , , , ductility vs. transformation temperature, hardness vs. transformation temperature, mechanical properties, Bakelite, see Phenol-formaldehyde (Bakelite) Balsa wood, sandwich panels, Band gap, – Band gap energy, determination of, selected semiconductors, Bands, see Energy bands Barcol hardness, Barium ferrite (as magnetic storage medium), Barium titanate: crystal structure, , – as dielectric, as ferroelectric, – as piezoelectric, Base (transistor), – Basic refractories, Basic slags, Bauxite ore, Beachmarks (fatigue), – Bend strength, . See also Flexural strength Beryllium-copper alloys, Beverage containers, , corrosion of, diffusion rate of CO through, – stages of production, Bifunctional repeat units, , Billiard balls, , Bimetallic strips, Binary eutectic alloys, – tensile strength, Binary isomorphous alloys, – mechanical properties, microstructure development, equilibrium cooling, – microstructure development, nonequilibrium cooling, – Biodegradable beverage can, Biodegradable polymers/plastics, – Biomass, Biomaterials, Biorenewable polymers/plastics, – Bioresorbability, Block copolymers, , , Blowing, of glass, Blow molding, plastics, Body-centered cubic structure, – , Burgers vector for, interstitial sites, tetrahedral and octahedral, – , , slip systems, twinning in, Boeing (Dreamliner), case study, – Bohr atomic model, , , Bohr magneton, , Boltzmann’s constant, , Bonding: carbon-carbon, cementitious, covalent, – , , hybrid sp, hybrid sp , – in graphite, hybrid sp , – in diamond, hybridization in carbon, – hydrogen, , , ionic, – , – , metallic, – , van der Waals, see van der Waals bonding Bonding energy, , and melting temperature for selected materials, Bonding forces, – Bonding tetrahedron, Bond rupture, in polymers, – Bone, as composite, Borazon, Boron carbide: hardness, Boron: boron-doped silicon semiconductors, fiber-reinforced composites, , properties as a fiber, Borosilicate glass: composition, electrical conductivity, viscosity, Borsic fi ber-reinforced composites, Bosons, Bottom-up science, Bragg’s law, – , Branched polymers, , • Index Brass, , , annealing behavior, elastic and shear moduli, electrical conductivity, fatigue behavior, phase diagram, , Poisson’s ratio, recrystallization temperature, stress corrosion, stress-strain behavior, thermal properties, yield and tensile strengths, ductility, Brazing, , Breakdown, dielectric, , Bridge, suspension, Brinell hardness tests, , – Brittle fracture, – , , , – , ceramics, – Brittle materials, thermal shock, – Bronze, , , photomicrograph, coring, Bronze age, Buckminsterfullerene, Buckyball, Burgers vector, , for FCC, BCC, and HCP, magnitude computation, Butadiene: degradation resistance, melting and glass transition temperatures, repeat unit structure, , Butane, – C Cadmium sulfide: color, electrical characteristics, Cadmium telluride, electrical characteristics, Calcination, , Calcite, Calcium fl uoride, bonding energy and melting temperature, Calendering, Capacitance, – , Capacitors, – Carbon: vs. graphite, , graphitic, nano, polymorphism, pyrolytic, turbostractic, Carbon black, as reinforcement in rubbers, , Carbon-carbon composites, , Carbon diffusion, in steels, , Carbon dioxide (pressure-temperature phase diagram), Carbon fiber-reinforced polymer-matrix composites, – , Carbon fibers, – in composites, , – properties as fiber, structure, Carbon monoxide emissions, Carbon nanotubes, applications, in nanocomposites, properties, Carborundum, . See also Silicon carbide. Carburizing, , , Case-hardened gear, Case hardening, , , Case studies: carbonated beverage containers, Liberty ship failures, – Cast alloys, Casting techniques: metals, – plastics, slip, – tape, – Cast irons, , , – , annealing, compositions, mechanical properties, and applications, graphite formation in, heat treatment effect on microstructure, phase diagram, , stress-strain behavior (gray), Catalysts, Catalytic converters (automobiles), , Cathodes, , Cathodic protection, , – , Cations, , Cemented carbide, – Cementite, – , decomposition, , proeutectoid, – in white iron, , Cementitious bond, Cements, , – , Ceramic-matrix composites, – , Ceramics, – , . See also Glass advanced, – application-classifi cation scheme, brittle fracture, – coeffi cientof thermal expansion values, , – color, corrosion, costs, – crystal structures, – summary, defects, – defined, – density computation, – density values, elastic modulus values, , – electrical conductivity values for selected, electrical resistivity values, – fabrication techniques classification, fl exural strength values, , – fractography of, – fracture toughness values, , impurities in, – indices of refraction, as electrical insulators, , magnetic, – mechanical properties of, – in MEMS, phase diagrams, – piezoelectric, , plastic deformation, Poisson’s ratio values, , porosity, – , – porosity, infl uence on properties, – silicates, – specifi c heat values, , as superconductors, thermal conductivity values, , thermal properties, , , – , traditional, traditional vs. new, translucency and opacity, Cercor (glass-ceramic), Cermets, , Cesium chloride structure, Chain-folded model, , Chain-reaction polymerization, see Addition polymerization Chain stiffening/stiffness, , Charge carriers: majority vs. minority, temperature dependence, – Charpy impact test, – , Chevron markings, – Chips, semiconductor, Chlorine, bonding energy and melting temperature, Chloroprene, repeat unit structure, , Chloroprene rubber: characteristics and applications, melting and glass transition temperatures, cis, , Clay, characteristics, Index • Clay products, , drying and fi ring, , – fabrication, – Cleavage (brittle fracture), Clinker, Close-packed ceramic crystal structures, – Close-packed metal crystal structures, – Coarse pearlite, – , , Coatings (polymer), Cobalt: atomic radius and crystal structure, Curie temperature, as ferromagnetic material, magnetization curves (single crystal), Coercivity (coercive force), , Cold work, percent, Cold working, . See also Strain hardening Collector, – Color, metals, nonmetals, – Colorants, , Compacted graphite iron, , , Compliance, creep, Component, , , Composites: aramid fiber-reinforced polymer, – carbon-carbon, , carbon fiber-reinforced polymer, – ceramic-matrix, – classifi cation scheme, costs, defi nition, , dispersion-strengthened, elastic behavior: longitudinal, – transverse, – fiber-reinforced, see Fiber-reinforced composites glass fiber-reinforced polymer, – hybrid, – , laminar, , , – , large-particle, – metal-matrix, – particle-reinforced, – production processes, – properties, glass-, carbon-, aramid-fi ber reinforced, recycling of, – rule of mixtures expressions, , , , , strength: longitudinal, transverse, stress-strain behavior, – structural, – Composition, conversion equations, – specifi cation of, – Compressibility, Compression molding, plastics, Compression tests, Compressive deformation, , Computers: semiconductors in, – magnetic drives in, – Concentration, , . See also Composition Concentration cells, Concentration gradient, , Concentration polarization, – , Concentration profile, , Concrete, – , electrical conductivity, plane strain fracture toughness, , Condensation polymerization, , Conducting polymers, – Conduction: electronic, ionic, , Conduction band, , Conductivity, see Electrical conductivity; Thermal conductivity Confi guration, molecular, – Conformation, molecular, Congruent phase transformations, – , Constitutional diagrams, see Phase diagrams Continuous casting, Continuous-cooling transformation diagrams, – , steel, . wt% C steel, . wt% C steel, . wt% C steel, for glass-ceramic, Continuous fibers, Conventional hard magnetic materials, Conversion factors, magnetic units, Cooling rate, of cylindrical rounds, Coordinates, point, – Coordination numbers, , , – , Copolymers, , – , styrenic block, – Copper: atomic radius and crystal structure, elastic and shear moduli, electrical conductivity, OFHC, Poisson’s ratio, recrystallization, , slip systems, thermal properties, yield and tensile strengths, ductility, Copper alloys, – properties and applications of, Copper-aluminum phase diagram, , Copper-beryllium alloys, , phase diagram, Copper-nickel alloys: ductility vs. composition, , electrical conductivity, phase diagram, – tensile strength vs. composition, , yield strength vs. composition, Copper-silver phase diagram, , Copper-zinc alloys, electrical resistivity vs. composition, Coring, CorningWare (glass-ceramic), Corrosion, of beverage cans, ceramic materials, electrochemistry of, – environmental effects, environments, – forms of, – galvanic series, , overview of, passivity, – , rates, – prediction of, – Corrosion fatigue, , Corrosion inhibitors, Corrosion penetration rate, – , Corrosion prevention, – Corundum, . See also Aluminum oxide crystal structure, front cover, Cost of various materials, – Coulombic force, , Covalency, degree of, Covalent bonding, – , , , Crack confi gurations, in ceramics, Crack critical velocity, Crack formation, in ceramics, fatigue and, glass, Crack propagation, . See also Fracture mechanics in brittle fracture, – in ceramics, – in ductile fracture, – fatigue and, – Cracks: stable vs. unstable, • Index Crack surface displacement modes, Crazing, Creep, – , ceramics, infl uence of temperature and stress on, – mechanisms, in polymers, , stages of, – , steady-state rate, viscoelastic, Creep compliance, Creep modulus, Creep rupture tests, data extrapolation, – Crevice corrosion, – , Cristobalite, , , Critical cooling rate: ferrous alloys, – glass-ceramics, Critical crack length (equation) leak-before-break, Critical fi ber length, – Critical resolved shear stress, , as related to dislocation density, Critical stress (fracture), Critical temperature, superconductivity, , Critical velocity (crack), , Crosslinking, , , elastomers, infl uence on viscoelastic behavior, , thermosetting polymers, Cross-ply, laminar composite, Crystalline materials, , , defects, – single crystals, , Crystallinity, polymers, – , infl uence on mechanical properties, – Crystallites, , Crystallization, polymers, – Crystallographic directions, – easy and hard magnetization, families, hexagonal crystals, – Crystallographic planes, – atomic arrangements, – close-packed, ceramics, – close-packed, metals, – diffraction by, – families, hexagonal crystals, – Crystallographic point coordinates, – Crystal structures, – , . See also Body-centered cubic structure; Close-packed crystal structures; Face-centered cubic structure; Hexagonal close-packed structure ceramics, – close-packed, ceramics, – close-packed, metals, – determination by x-ray diffraction, – selected metals, types, ceramics, – , – types, metals, – , – Crystallization (ceramics), , , Crystal systems, – , Cubic crystal system, Cubic ferrites, – Cunife, , Cup-and-cone fracture, Curie temperature, , ferroelectric, ferromagnetic, Curing, plastics, Current density, Cyclic stresses, – D Damping capacity, steel vs. cast iron, Data scatter, – Debye temperature, Decarburization, Defects, see also Dislocations atomic vibrations and, dependence of properties on, in ceramics, – , interfacial, – point, – , in polymers, surface, volume, Defect structure, , Deformation: elastic, see Elastic deformation elastomers, plastic, see Plastic deformation Deformation mechanism maps (creep), Deformation mechanisms (semicrystalline polymers), elastic deformation, plastic deformation, – Degradation of polymers, – , Degree of polymerization, , Degrees of freedom, Delayed fracture, – Density: computation for ceramics, – computation for metal alloys, computation for metals, computation for polymers, of dislocations, linear atomic, – planar atomic, – polymers (values for), – ranges for material types (bar chart), relation to percent crystallinity for polymers, values for various materials, – Desiccants, Design, component, Design examples: cold work and recrystallization, – conductivity of a p-type semiconductor, – cubic mixed-ferrite magnet, – creep rupture lifetime for an S- steel, materials specification, pressurized cylindrical tank, – nonsteady-state diffusion, – pressurized cylindrical tube, – steel shaft, alloy/heat treatment of, – tensile-testing apparatus, – tubular composite shaft, – Design factor, Design stress, , Dezincifi cation, of brass, Diamagnetism, – , Diamond, , – as abrasive, bonding energy and melting temperature, cost, hardness, properties and applications, – thermal conductivity value, , Diamond cubic structure, Die casting, Dielectric breakdown, , Dielectric constant, , frequency dependence, – relationship to refractive index, selected ceramics and polymers, Dielectric displacement, , Dielectric loss, Dielectric materials, – , , Dielectric strength, , selected ceramics and polymers, Diffraction (x-ray), – , Diffraction angle, Diffractometers, Diffusion, – , drive-in, grain growth and, , in ionic materials, – in integrated circuit interconnects, – in Si of Cu, Au, Ag, and Al, interstitial, – , mechanisms, – Index • and microstructure development, – , nonsteady-state, – , in polymers, – predeposition, semiconductors, in semiconductors, – short-circuit, steady-state, – , vacancy, – , , Diffusion coefficient, , data (tabulation), various metal systems, relation to ionic mobility, temperature dependence, – Diffusion couples, , Diffusion flux, , for polymers, Diffusivity, thermal, Digital camera, Digitization of information/signals, , Dimethyl ether, Dimethylsiloxane, , , , . See also Silicones; Silicone rubber melting and glass transition temperatures, Dimethyl terephthalate (structure), Diode, , Diode lasers, Dipole moment, Dipoles: electric, , induced, magnetic, – permanent, Directional solidification, Directions, see Crystallographic directions Discontinuous fibers, Dislocation density, , , , Dislocation line, , , , Dislocation motion, – caterpillar locomotion analogy, in ceramics, at grain boundaries, – infl uence on strength, recovery and, Dislocations, – , in ceramics, , , characteristics of, – interactions, multiplication, at phase boundaries, , pile-ups, plastic deformation and, , – in polymers, , strain fields, – Dispersed phase, , definition, geometry, Dispersion (optical), white light through a prism, Dispersion-strengthened composites, , Disposal of materials, – Domain growth, – iron single crystal, Domains (magnetic), , , , photograph of, Domain walls, Donors, , Doping, , , Double bonds, Drain casting, – Drawing: glass, infl uence on polymer properties, – metals, , polymer fibers, , Dreamliner (Boeing ), case study, – Drift velocity, electron, Drive-in diffusion, Driving force, , electrochemical reactions, grain growth, recrystallization, sintering, steady-state diffusion, Dry corrosion, Dry ice, Drying, clay products, – Ductile fracture, – , – , Ductile iron, , , compositions, mechanical properties, and applications, Ductile-to-brittle transition, – , failure of Liberty ships, – polymers, and temper embrittlement, Ductility, – , bainite, pearlite vs. transformation temperature, fi ne and coarse pearlite, precipitation hardened aluminum alloy, selected materials, , – spheroidite, temperedmartensite, Durometer hardness, , E Economics, materials selection: considerations in materials engineering, – pressurized cylindrical tube, – tubular composite shaft, – Eddy currents, Edge dislocations, , – , . See also Dislocations interactions, – EEPROM memory, E-glass, , Elastic deformation, – , Elastic modulus, see Modulus of elasticity Elastic (strain) recovery, , , Elastomers, , – , – , , in composites, deformation, thermoplastic, – trade names, properties, and applications, Electrical conduction: in insulators and semiconductors, – in metals, Electrical conductivity, , , ranges for material types (bar chart), selected ceramics and polymers, selected metals, selected semiconductors, temperature variation (Ge), values for electrical wires, Electrical resistivity, , . See also Electrical conductivity metals: infl uence of impurities, infl uence of plastic deformation, , infl uence of temperature, – values for various materials, – Electrical wires, aluminum and copper, – Electric dipole moment, Electric dipoles, see Dipoles Electric fi eld, , , Electrochemical cells, – Electrochemical reactions, – Electrodeposition, Electrode potentials, – values of, Electroluminescence, , in polymers, Electrolytes, , Electromagnetic radiation, – interactions with atoms/electrons, – Electromagnetic spectrum, – Electron band structure, see Energy bands Electron cloud, Electron configurations, – , elements, periodic table and, – stable, Diffusion (Continued) • Index Electronegativity, , , infl uence on solid solubility, values for the elements, Electroneutrality, , Electron gas, Electron orbital shapes, – Electronic conduction, , Electronic polarization, , , , Electron microscopy, – Electron mobility, infl uence of dopant content on, infl uence of temperature on, – selected semiconductors, Electron orbitals, Electron probability distribution, , Electrons, conduction process, , – role, diffusion in ionic materials, energy bands, see Energy bands energy levels, – free, see Free electrons scattering, – , in semiconductors, – temperature variation of concentration, – spin, , – valence, Electron states, Electron transitions, – metals, – nonmetals, – Electron volt, , Electronic waste, Electropositivity, , Electrorheological fluids, Elongation, percent, selected materials, , – selected metals, selected polymers, Embrittlement: hydrogen, – temper, Embryo, phase particle, – Emery, Emf series, – , Emitter, Emulsifiers, Endurance limit, . See also Fatigue limit Energy: activation, see Activation energy bonding, – , current concerns about, , – free, , , – , grain boundary, to magnetize ferromagnetic material, photon, surface, vacancy formation, Energy band gap, see Band gap Energy bands, – structures for metals, insulators, and semiconductors, Energy levels (states), – , – Engineered materials, , Energy product, magnetic, – Engineering stress/strain, , Entropy, , , Environmental considerations and materials, – Epoxies: degradation resistance, polymer-matrix composites, repeat unit structure, trade names, characteristics, and applications, Equilibrium: defi nition of, phase, – , Equilibrium diagrams, see Phase diagrams Erosion-corrosion, – , Error bars, Error function, Gaussian, Etching, Ethane, Ethers, Ethylene, polymerization, – Ethylene glycol (structure), Euro coins, alloys used for, Eutectic isotherm, Eutectic phase, , Eutectic reactions, , , iron-iron carbide system, Eutectic structure, , Eutectic systems: binary, – microstructure development, , – Eutectoid, shift of position, Eutectoid ferrite, Eutectoid reactions, , iron-iron carbide system, kinetics, – Eutectoid steel, microstructure changes/ development, – Exchange current density, Excited states, , Exhaustion, in extrinsic semiconductors, Expansion, thermal, see Thermal expansion Extrinsic semiconductors, – , electron concentration vs. temperature, exhaustion, saturation, Extrusion, clay products, metals, polymers, F Fabrication: ceramics, – clay products, – fi ber-reinforced composites, – metals, – Face-centered cubic structure, – , anion stacking (ceramics), – Burgers vector for, close packed planes (metals), – interstitial sites, tetrahedral and octahedral, – , , slip systems, – Factor of safety, Failure, mechanical, see Creep; Fatigue; Fracture Faraday constant, Fatigue, – , corrosion, crack initiation and propagation, – cyclic stresses, – environmental effects, – low- and high-cycle, polymers, – probability curves, thermal, Fatigue damage, commercial aircraft, Fatigue life, , factors that affect, – Fatigue limit, , , Fatigue S-N curves, – for metals, for polymers, Fatigue strength, , , Fatigue testing, – Feldspar, Fermi energy, , , , Ferrimagnetism, – , temperature dependence, Ferrite (α), – , eutectoid/proeutectoid, – , from decomposition of cementite, Ferrites (magnetic ceramics), – , Curie temperature, as magnetic storage, Ferritic stainless steels, , Ferroelectricity, – , Ferroelectric materials, – Ferromagnetic domain walls, Ferromagnetism, – , temperature dependence, Ferrous alloys, . See also Cast irons; Iron; Steels annealing, – classifi cation, , continuous-cooling transformation diagrams, – Index • costs, – hypereutectoid, – , hypoeutectoid, – , isothermal transformation diagrams, – microstructures, – mechanical properties of, – , – Fiber effi ciency parameter, , Fiberglass, Fiberglass-reinforced composites, – Fiber-reinforced composites, – , continuous and aligned, – discontinuous and aligned, discontinuous and randomly oriented, – fi ber length effect, – fi ber orientation/concentration effect, – fi ber phase, – longitudinal loading, – , – matrix phase, processing, – reinforcement efficiency, transverse loading, – , Fibers, – , carbon: graphitic, structure, turbostratic, coeffi cientof thermal expansion values, in composites, continuous vs. discontinuous, – fi ber phase, – length effect, – orientation and concentration, – costs, density values, elastic modulus values, , electrical resistivity values, optical, – polymer, – properties of selected, specifi c heat values, spinning of, tensile strength values, , thermal conductivity values, Fick’s fi rst law, , , for polymers, Fick’s second law, – , , solutions to, , , Fictive temperature, Filament winding, – Fillers, , Films: polymer, shrink-wrap (polymer), Fine pearlite, , , – , , , Firing, , – , Flame retardants, , Flash memory, , Flash memory cards, Flexural defl ection, equation for, Flexural strength, – , infl uence of porosity on, ceramics, – values for selected ceramics, , – Float process (sheet glass), Fluorescence, , Fluorite structure, Fluorocarbons, trade names, characteristics, and applications, Flux (clay products), , Foams, , Forces: bonding, – coulombic, , Forging, , , Formaldehyde, Forming operations (metals), – Forsterite, Forward bias, , , Fractographic investigations: ceramics, – metals, Fractographs: cup-and-cone fracture surfaces, fatigue striations, glass rod, intergranular fracture, transgranular fracture, Fracture, see also Brittle fracture; Ductile fracture; Impact fracture testing delayed, – fundamentals of, of Liberty ships, – polymers, – types, – , – Fracture mechanics, , applied to ceramics, – polymers, use in design, – Fracture profiles, Fracture strength, . See also Flexural strength ceramics, – distribution of, infl uence of porosity, – infl uence of specimen size, , – Fracture surface, ceramics, – Fracture toughness, , – , ceramic-matrix composites, – ranges for material types (bar chart), testing, values for selected materials, , – Free electrons, , contributions to heat capacity, role in heat conduction, Free energy, , – , activation, , volume, Freeze-out region, Frenkel defects, , , equilibrium number, Full annealing, , , Fullerenes, applications, properties, Functionality (polymers), , Furnace heating elements, Fused silica, characteristics, , dielectric properties, electrical conductivity, fl exural strength, index of refraction, modulus of elasticity, thermal properties, G Gadolinium, , Gallium arsenide: cost, electrical characteristics, , for lasers, for light-emitting diodes, , Gallium phosphide: electrical characteristics, for light-emitting diodes, Galvanic corrosion, – , Galvanic couples, Galvanic series, , , Galvanized steel, , Garnets, Garnet single crystal, Gas constant, , Gating system, Gauge length, , Gaussian error function, Gears (transmission), Gecko lizard, Geometric isomerism, – Germanium: electrical characteristics, , , Gibbs phase rule, – , Gilding metal, Ferrous alloys (Continued) • Index Glass: annealing, , blowing, classification, color, commercial, compositions and characteristics, corrosion resistance, cost, – dielectric properties, electrical conductivity, fl exural strength, , forming techniques, – fracture surface (photomicrograph), hardness, heat treatment, – melting point, modulus of elasticity, , optical flint, plane strain fracture toughness, , refractive index, sheet forming (fl oat process), soda-lime, composition, softening point, strain point, stress-strain behavior, surface crack propagation, tempering, – , thermal properties, viscous properties, working point, , Glass-ceramics, – , composition (Pyroceram), continuous-cooling transformation diagram, fabricating and heat treating, – fl exural strength, , modulus of elasticity, , optical transparency, conditions for, properties and applications, Glass fibers, fiberglass-reinforced composites, – , forming, properties as fiber, Glass transition, polymers, Glass transition temperature, , , , factors that affect, polymers, values for selected polymers, , Glucydur, low-expansion alloy used in wristwatches, Gold, atomic radius and crystal structure, electrical conductivity, slip systems, thermal properties, Graft copolymers, , , Grain boundaries, , – , Grain boundary energy, Grain growth, – , Grains, definition, distortion during plastic deformation, – Grain size, dependence on time, – determination of, – linear intercept method for determination of, , mechanical properties and, – reduction, and strengthening of metals, – refinement by annealing, Grain size number (ASTM), Graphene, – applications, in nanocomposites, properties, Graphite, – applications, in cast irons, compared to carbon, , cost, from decomposition of cementite, electrical conductivity, properties, properties as whisker, as a refractory, structure of, Gray cast iron, – , compositions, mechanical properties, and applications, Green ceramic bodies, , Green design, Ground state, , , Growth, phase particle, , – , rate, – temperature dependence of rate, Gutta percha, H Hackle region, – Half-cells, standard, Half-reactions, Hall coefficient, Hall effect, – , Hall-Petch equation, Hall voltage, Halogens, Hard disk drives, – Hardenability, – , Hardenability band, , Hardenability curves, – Hard magnetic materials, – , properties, Hardness, bainite, pearlite vs. transformation temperature, ceramics, – comparison of scales, conversion diagram, correlation with tensile strength, – fi ne and coarse pearlite, spheroidite, pearlite, martensite, tempered martensite, polymers, tempered martensite, , Hardness tests, – summary of tests, Hard sphere model, Head-to-head configuration, Head-to-tail configuration, Heat affected zone, Heat capacity, – , temperature dependence, vibrational contribution, Heat flux, Heat of fusion, latent, Heat transfer: mechanism, , – nonsteady-state, Heat treatable, defi nition of, Heat treatments, . See also Annealing; Phase transformations dislocation density reduction, glass, – hydrogen embrittlement, – intergranular corrosion and, – polymer morphology, polymer properties, for precipitation hardening, – recovery, recrystallization, and grain growth during, – steel, – Henry (magnetic unit), Hertz, Heterogeneous nucleation, , – Hexagonal close-packed structure, – , , anion stacking (ceramics), Burgers vector for, close-packed planes (metals), – slip systems, twinning in, – unit cell volume, Hexagonal crystal system, direction indices, – planar indices, – Hexagonal ferrites, Hexamethylene diamine, , Hexane, High-carbon steels, High-cycle fatigue, Index • High polymers, , High-strength, low-alloy (HSLA) steels, , High-temperature superconductors, Holes, , , role, diffusion in ionic materials, mobility: infl uence of dopant concentration on, infl uence of temperature on, values for selected semiconductors, temperature dependence of concentration (Si, Ge), Homogeneous nucleation, – Homopolymers, , Honeycomb structure, use in Boeing Dreamliner, Hooke’s law, , Hoop stress (equation for cylinder), Hot pressing, Hot working, , , . See also Heat treatments HSLA (high-strength, low-alloy) steels, , Hume-Rothery rules, Hund’s rule, Hybrid composites, – , Hybridized bonding, in carbon, – Hydration, of cement, Hydrocarbons, – Hydrogen: diffusive purifi cation, , reduction, , Hydrogen bonding, , , water expansion upon freezing, Hydrogen chloride, , Hydrogen electrode, Hydrogen embrittlement, – , Hydrogen fl uoride, , bonding energy and melting temperature, Hydrogen induced cracking, Hydrogen stress cracking, Hydroplastic forming, , Hydroplasticity, Hydrostatic powder pressing, Hypereutectoid alloys, – , Hypoeutectoid alloys, – , Hysteresis (magnetic), – Hysteresis, ferromagnetic, soft and hard magnetic materials, , – I Ice, , , , , Iceberg, Impact energy, , fi ne pearlite, temperature dependence: high-strength materials, low-strength FCC and HCP metals, low-strength steels, , Impact fracture testing, – Impact strength, polymers, Imperfections. See Defects; Dislocations Impurities: in ceramics, – diffusion, electrical resistivity, in metals, – thermal conductivity, Incongruent phase transformation, Index of refraction, – , selected materials, Indices, Miller, , Indium antimonide, bonding energy and melting temperature, electrical characteristics, Indium phosphide, electrical characteristics, in light-emitting diodes, Induced dipoles, Inert gases, , Inhibitors, , Initial permeability, Injection molding, , Ink-jet printer heads, piezoelectric ceramics in, – Insulators (electrical), . See also Dielectric materials ceramics and polymers as, , color, defined, electron band structure, translucency and opacity, – Integrated circuits, – , interconnects, – scanning electron micrograph, , Interatomic bonding, – Interatomic separation, Interconnects, integrated circuits, – Interdiffusion, , Interfacial defects, – Interfacial energies, for heterogeneous nucleation, Intergranular corrosion, – , Intergranular fracture, , , Intermediate solid solutions, , , Intermetallic compounds, – , , , International Organization for Standardization (ISO), Interplanar spacing: cubic crystals, – orthorhombic crystals, Interstitial diffusion, – , Interstitial impurity defects, Interstitials: in ceramics, – in polymers, self-, , Interstitial sites, FCC and BCC, – , , Interstitial solid solutions, , Intrinsic carrier concentration, temperature dependence for Si and Ge, Intrinsic conductivity, – Intrinsic semiconductors, – , Invar, Material of Importance, – thermal properties, Invariant point, Inverse lever rule, . See Lever rule Inverse spinel structure, – Ion cores, Ionic bonding, – , in ceramics, forces and energies, – Ionic character (percent), – , Ionic conduction, , , Ionic polarization, , Ionic radii, – , Iridium, Iron, see also Ferrous alloys; Steels atomic radius and crystal structure, Curie temperature, electrical conductivity, ferrite (α), , , , as ferromagnetic material, magnetic properties, magnetization curves (single crystal), polymorphism, recrystallization temperature, rolling texture, slip systems, stress-strain behavior (at three temperatures), thermal properties, yield and tensile strengths, ductility, Iron age, Iron-carbon alloys, see Ferrous alloys Iron-iron carbide alloys, – Iron-silicon alloy, magnetic properties, Material of Importance (use in transformer cores), Isobutane, Isobutylene, Isomerism, , geometric, – stereoisomerism, – Isomorphous systems, , binary, see Binary isomorphous alloys Isoprene, • Index ISO (International Organization for Standardization), Isostatic powder pressing, Isostrain, in fiber-reinforced composites, Isostress, in fiber-reinforced composites, Isotactic confi guration, , , Isothermal, Isothermal transformation diagrams, – , alloy steel, . wt% C steel, . wt% C steel, . wt% C steel, Isotopes, , Isotropic materials, , Izod impact test, – , J Jominy end-quench test, – , Junction depth, diffusion, Junction transistors, – , K Kaolinite clay, – , Kevlar, see Aramid Kinetics, – , crystallization of polymers, – oxidation, – phase transformations, – Knoop hardness, , Kovar: as low-expansion alloy, – thermal properties, Krypton, bonding energy and melting temperature, L Ladder polymer, Lamellae (polymers), Laminar composites, – , angle-ply, carbon fiber-epoxy, Boeing Dreamliner, – cross-ply, multidirectional, unidirectional, Large-particle composites, – , Larson-Miller parameter, – plots of, , Lasers, – , semiconductor, – , types, characteristics, and applications, Laser beam welding, Latent heat of fusion, Latex, Lattice parameters, , Lattices, , Lattice strains, – , – , , Lattice waves, Laue photograph, , Layered silicates, – Lay-up, in prepreg processing, Lead, atomic radius and crystal structure, diffraction pattern, recrystallization temperature, superconducting critical temperature, Lead-free solders, Lead oxide, crystal structure, Lead-tin phase diagram, , – Lead titanate, Lead zirconate, Lead-zirconate-titanate, , Leak-before-break design, Leathery region, polymers, – LEDs, see Light-emitting diodes Lever rule, – , Life cycle analysis/assessment, Light: absorption, – reflection, refraction, – scattering, – transmission, Light-emitting diodes, organic, – polymer, – semiconductor, Lime, Linear atomic density, Linear coeffi cient of thermal expansion, , – , , , values for selected materials, , – Linear corrosion rate, Linear defects, – Linear polymers, , Liquid crystal polymers, – , Liquidus line, , , , Liquidus temperatures: solders, Cu-Au system, Lithium fl uoride, bonding energy and melting temperature, Lodestone (magnetite), , Logarithmic corrosion rate, Longitudinal direction, – , Longitudinal loading, composites, – , – Lost-foam casting, Lost-wax casting, Low-angle grain boundaries, see Small-angle grain boundaries Low-carbon steels, – Low-cycle fatigue, Lower critical temperature (ferrous alloys), – , Lower yield point, , Low-expansion alloys, – in wristwatches, Luminescence, , M Macromolecules, , Magnesia, see Magnesium oxide Magnesium: automobile wheel, diffraction pattern, elastic and shear moduli, Poisson’s ratio, single crystal (cleaved), slip systems, Magnesium alloys, , Magnesium fluoride, optical properties
كلمة سر فك الضغط : books-world.net The Unzip Password : books-world.net أتمنى أن تستفيدوا من محتوى الموضوع وأن ينال إعجابكم رابط من موقع عالم الكتب لتنزيل كتاب Fundamentals of Materials Science and Engineering - An Integrated Approach رابط مباشر لتنزيل كتاب Fundamentals of Materials Science and Engineering - An Integrated Approach
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