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Introduction to Materials Science for Engineers, Global Edition de James Shackelford

Introduction to Materials Science for Engineers, Global Edition

Autor James Shackelford, James F. Shackelford
en Limba Engleză Paperback – 14 noi 2022
For a first course in Materials Sciences and Engineering taught in the departments of materials science, mechanical, civil and general engineering.
Introduction to Materials Science for Engineers provides balanced, current treatment of the full spectrum of engineering materials, covering all the physical properties, applications and relevant properties associated with engineering materials. It explores all of the major categories of materials while also offering detailed examinations of a wide range of new materials with high-tech applications.
Revised to reflect recent data and trends, the 9th Edition includes updated computer-generated crystal structure illustrations and new end-of-chapter conceptual problems.
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Specificații

ISBN-13: 9781292440996
ISBN-10: 1292440996
Pagini: 704
Dimensiuni: 204 x 253 x 26 mm
Greutate: 1.27 kg
Ediția:9. Auflage
Editura: Pearson

Notă biografică

JamesF. Shackelford has BS and MS degrees in Ceramic Engineeringfrom the University of Washington and a Ph.D. in Materials Science andEngineering from the University of California, Berkeley. Following apostdoctoral fellowship at McMaster University in Canada, he joined theUniversity of California, Davis, where he is currently Distinguished ProfessorEmeritus in the Department of Materials Science and Engineering. For manyyears, he served as the Associate Dean for Undergraduate Studies in the Collegeof Engineering and later as the Director of the University Honors Program thatserves students from a wide spectrum of majors. Dr. Shackelford also served asAssociate Director for Education for the National Science Foundation(NSF)-funded Center for Biophotonics Science and Technology (CBST) and asFaculty Assistant to the Director of the McClellan Nuclear Research Center(MNRC) of UC Davis. He teaches and conducts research in the structural characterizationand processing of materials, focusing on glasses and biomaterials. His currentfocus in teaching is doing so through online technologies. A member of theAmerican Ceramic Society and ASM International, he was named a Fellow of theAmerican Ceramic Society in 1992, was named a Fellow of ASM International in2011, and received the Outstanding Educator Award of the American CeramicSociety in 1996 and the Albert Easton White Distinguished Teacher Award fromASM International in 2019. In 2003, he received a Distinguished Teaching Awardfrom the Academic Senate of the University of California, Davis. In 2012, hereceived the Outstanding Teaching Award of the College of Engineering at UCDavis, and, in 2014, received an Outstanding Service Award from UC DavisExtension. In 2016, Professor Shackelford received the Inaugural Award forOutstanding Contributions to Materials Education at the North AmericanMaterials Education Symposium (NAMES) held at the University of California,Berkeley. He has published over 150 archived papers and books including Introductionto Materials Science for Engineers now in its 9th Edition and whichhas been translated into Chinese, German, Italian, Japanese, Korean,Portuguese, and Spanish.

Cuprins

  1. Materials for Engineering
    • 1.1 The Material World
    • 1.2 Materials Science and Engineering
    • 1.3 Six Materials That Changed Your World
      • STEEL BRIDGESINTRODUCING METALS
      • TRANSPARENT OXIDESINTRODUCING CERAMICS
      • SMARTPHONES AND TABLETSINTRODUCING GLASSES
      • NYLON PARACHUTESINTRODUCING POLYMERS
      • KEVLAR�-REINFORCED TIRESINTRODUCINGCOMPOSITES
      • SILICON CHIPSINTRODUCING SEMICONDUCTORS
    • 1.4 Processing and Selecting Materials
    • 1.5 Looking at Materials by Powers of Ten
PARTI: The Fundamentals
  • Atomic Bonding
    • 2.1 Atomic Structure
    • 2.2 The Ionic Bond
    • COORDINATION NUMBER
    • 2.3 The Covalent Bond
    • 2.4 The Metallic Bond
    • 2.5 The Secondary, or van der Waals, Bond
    • 2.6 MaterialsThe Bonding Classification
  • Crystalline StructurePerfection
    • 3.1 Seven Systems and Fourteen Lattices
    • 3.2 Metal Structures
    • 3.3 Ceramic Structures
  • Crystal Defects and Noncrystalline StructureImperfection
    • 4.1 The Solid SolutionChemical Imperfection
    • 4.2 Point DefectsZero-Dimensional Imperfections
    • 4.3 Linear Defects, or DislocationsOne-Dimensional Imperfections
    • 4.4 Planar DefectsTwo-Dimensional Imperfections
    • 4.5 Noncrystalline SolidsThree-Dimensional Imperfections
  • Diffusion
    • 5.1 Thermally Activated Processes
    • 5.2 Thermal Production of Point Defects
    • 5.3 Point Defects and Solid-State Diffusion
    • 5.4 Steady-State Diffusion
    • 5.5 Alternate Diffusion Paths
  • Mechanical Behavior
    • 6.1 Stress Versus Strain
    • METALS
    • CERAMICS AND GLASSES
    • POLYMERS
    • 6.2 Elastic Deformation
    • 6.3 Plastic Deformation
    • 6.4 Hardness
    • 6.5 Creep and Stress Relaxation
    • 6.6 Viscoelastic Deformation
    • INORGANIC GLASSES
    • ORGANIC POLYMERS
    • ELASTOMERS
  • Thermal Behavior
    • 7.1 Heat Capacity
    • 7.2 Thermal Expansion
    • 7.3 Thermal Conductivity
    • 7.4 Thermal Shock
  • Failure Analysis and Prevention
    • 8.1 Impact Energy
    • 8.2 Fracture Toughness
    • 8.3 Fatigue
    • 8.4 Nondestructive Testing
    • 8.5 Failure Analysis and Prevention
  • Phase DiagramsEquilibrium Microstructural Development
    • 9.1 The Phase Rule
    • 9.2 The Phase Diagram
    • COMPLETE SOLID SOLUTION EUTECTIC DIAGRAM WITH NO SOLID SOLUTION
    • EUTECTIC DIAGRAM WITH LIMITED SOLID SOLUTION
    • EUTECTOID DIAGRAM
    • PERITECTIC DIAGRAM
    • GENERAL BINARY DIAGRAMS
    • 9.3 The Lever Rule
    • 9.4 Microstructural Development During Slow Cooling
  • TimeThe Third Dimension
    • 10.1 TimeThe Third Dimension
    • 10.2 The TTT Diagram
    • DIFFUSIONAL TRANSFORMATIONS
    • DIFFUSIONLESS (MARTENSITIC) TRANSFORMATIONS
    • HEAT TREATMENT OF STEEL
    • 10.3 Hardenability
    • 10.4 Precipitation Hardening
    • 10.5 Annealing
    • COLD WORK
    • RECOVERY
    • RECRYSTALLIZATION
    • GRAIN GROWTH
    • 10.6 The Kinetics of Phase Transformations for Nonmetals
    PART II: Materials and Their Applications
  • Structural MaterialsMetals, Ceramics, and Glasses
    • 11.1 Metals
    • FERROUS ALLOYS
    • NONFERROUS ALLOYS
    • 11.2 Ceramics and Glasses
    • CERAMICSCRYSTALLINE MATERIALS
    • GLASSESNONCRYSTALLINE MATERIALS
    • GLASS-CERAMICS
    • 11.3 Processing the Structural Materials
    • PROCESSING OF METALS
    • PROCESSING OF CERAMICS AND GLASSES
  • Structural MaterialsPolymers and Composites
    • Polymers
    • POLYMERIZATION
    • STRUCTURAL FEATURES OF POLYMERS
    • THERMOPLASTIC POLYMERS
    • THERMOSETTING POLYMERS
    • ADDITIVES
    • 12.2 Composites
    • FIBER-REINFORCED COMPOSITES
    • AGGREGATE COMPOSITES
    • PROPERTY AVERAGING
    • MECHANICAL PROPERTIES OF COMPOSITES
    • 12.3 Processing the Structural Materials
    • PROCESSING OF POLYMERS
    • PROCESSING OF COMPOSITES
  • Electronic Materials
    • 13.1 Charge Carriers and Conduction
    • 13.2 Energy Levels and Energy Bands
    • 13.3 Conductors
    • THERMOCOUPLES
    • SUPERCONDUCTORS
    • 13.4 Insulators
    • FERROELECTRICS
    • PIEZOELECTRICS
    • 13.5 Semiconductors
    • INTRINSIC, ELEMENTAL SEMICONDUCTORS
    • EXTRINSIC, ELEMENTAL SEMICONDUCTORS
    • COMPOUND SEMICONDUCTORS
    • PROCESSING OF SEMICONDUCTORS
    • SEMICONDUCTOR DEVICES
    • 13.6 Composites
    • 13.7 Electrical Classification of Materials
  • Optical and Magnetic Materials
    • 14.1 Optical Materials
    • OPTICAL PROPERTIES
    • OPTICAL SYSTEMS AND DEVICES
    • 14.2 Magnetic Materials
    • FERROMAGNETISM
    • FERRIMAGNETISM
    • METALLIC MAGNETS
    • CERAMIC MAGNETS
  • Materials in Engineering Design
    • 15.1 Material PropertiesEngineering Design Parameters
    • 15.2 Selection of Structural MaterialsCase Studies
    • MATERIALS FOR HIP- AND KNEE-JOINT REPLACEMENT
    • METAL SUBSTITUTION WITH COMPOSITES
    • 15.3 Selection of Electronic, Optical, and Magnetic MaterialsCase Studies
    • LIGHT-EMITTING DIODE
    • GLASS FOR SMART PHONE AND TABLET TOUCHSCREENS
    • AMORPHOUS METAL FOR ELECTRIC-POWERDISTRIBUTION
    • 15.4 Materials and Our Environment
    • ENVIRONMENTAL DEGRADATION OF MATERIALS
    • ENVIRONMENTAL ASPECTS OF DESIGN RECYCLING AND REUSE
    • APPENDIX1: Physical and Chemical Data for the Elements
    • APPENDIX 2: Atomic and Ionic Radii of the Elements
    • APPENDIX 3: Constants and Conversion Factors and the Periodic Table of Elements
    • APPENDIX 4: Properties of the Structural Materials
    • APPENDIX 5: Properties of the Electronic, Optical, and Magnetic Materials
    • APPENDIX 6: Glossary Answers to Practice Problems (PP) and Odd-Numbered Problems Index