LEADER 05358nam  22006494a 450 
001 9910143560503321
005 20230617002431.0
010   $a1-280-25481-5
010   $a9786610254811
010   $a0-470-32412-0
010   $a0-471-71164-0
010   $a0-471-71163-2
035   $a(CKB)1000000000355334
035   $a(EBL)226604
035   $a(OCoLC)559961276
035   $a(SSID)ssj0000145217
035   $a(PQKBManifestationID)11162097
035   $a(PQKBTitleCode)TC0000145217
035   $a(PQKBWorkID)10156283
035   $a(PQKB)10343406
035   $a(MiAaPQ)EBC226604
035   $a(Au-PeEL)EBL226604
035   $a(CaPaEBR)ebr10114172
035   $a(CaONFJC)MIL25481
035   $a(EXLCZ)991000000000355334
100   $a20040716d2005      uy             0
101 0 $aeng
135   $aur|n|---|||||
181   $ctxt
182   $cc
183   $acr
200 10$aElectronic materials science$b[electronic resource] /$fEugene A. Irene
210   $aHoboken, N.J. $cWiley-Interscience$dc2005
215   $a1 online resource (322 p.)
300   $aDescription based upon print version of record.
311   $a0-471-69597-1 
320   $aIncludes bibliographical references and index.
327   $aELECTRONIC MATERIALS SCIENCE; CONTENTS; Preface; 1 Introduction to Electronic Materials Science; 1.1 Introduction; 1.2 Structure and Diffraction; 1.3 Defects; 1.4 Diffusion; 1.5 Phase Equilibria; 1.6 Mechanical Properties; 1.7 Electronic Structure; 1.8 Electronic Properties and Devices; 1.9 Electronic Materials Science; 2 Structure of Solids; 2.1 Introduction; 2.2 Order; 2.3 The Lattice; 2.4 Crystal Structure; 2.5 Notation; 2.5.1 Naming Planes; 2.5.2 Lattice Directions; 2.6 Lattice Geometry; 2.6.1 Planar Spacing Formulas; 2.6.2 Close Packing; 2.7 The Wigner-Seitz Cell; 2.8 Crystal Structures
327   $a2.8.1 Structures for Elements2.8.2 Structures for Compounds; 2.8.3 Solid Solutions; Related Reading; Exercises; 3 Diffraction; 3.1 Introduction; 3.2 Phase Difference and Bragg's Law; 3.3 The Scattering Problem; 3.3.1 Coherent Scattering from an Electron; 3.3.2 Coherent Scattering from an Atom; 3.3.3 Coherent Scattering from a Unit Cell; 3.3.4 Structure Factor Calculations; 3.4 Reciprocal Space, RESP; 3.4.1 Why Reciprocal Space?; 3.4.2 Definition of RESP; 3.4.3 Definition of Reciprocal Lattice Vector; 3.4.4 The Ewald Construction; 3.5 Diffraction Techniques; 3.5.1 Rotating Crystal Method
327   $a3.5.2 Powder Method3.5.3 Laue Method; 3.6 Wave Vector Representation; Related Reading; Exercises; 4 Defects in Solids; 4.1 Introduction; 4.2 Why Do Defects Form?; 4.2.1 Review of Some Thermodynamics Ideas; 4.3 Point Defects; 4.4 The Statistics of Point Defects; 4.5 Line Defects-Dislocations; 4.5.1 Edge Dislocations; 4.5.2 Screw Dislocations; 4.5.3 Burger's Vector and the Burger Circuit; 4.5.4 Dislocation Motion; 4.6 Planar Defects; 4.6.1 Grain Boundaries; 4.6.2 Twin Boundaries; 4.7 Three-Dimensional Defects; Related Reading; Exercises; 5 Diffusion in Solids
327   $a5.1 Introduction to Diffusion Equations5.2 Atomistic Theory of Diffusion: Fick's Laws and a Theory for the Diffussion Construct D; 5.3 Random Walk Problem; 5.3.1 Random Walk Calculations; 5.3.2 Relation of D to Random Walk; 5.3.3 Self-Diffusion Vacancy Mechanism in a FCC Crystal; 5.3.4 Activation Energy for Diffusion; 5.4 Other Mass Transport Mechanisms; 5.4.1 Permeability versus Diffusion; 5.4.2 Convection versus Diffusion; 5.5 Mathematics of Diffusion; 5.5.1 Steady State Diffusion-Fick's First Law; 5.5.2 Non-Steady State Diffusion-Fick's Second Law; Related Reading; Exercises
327   $a6 Phase Equilibria6.1 Introduction; 6.2 The Gibbs Phase Rule; 6.2.1 Definitions; 6.2.2 Equilibrium Among Phases-The Phase Rule; 6.2.3 Applications of the Phase Rule; 6.2.4 Construction of Phase Diagrams: Theory and Experiment; 6.2.5 The Tie Line Principle; 6.2.6 The Lever Rule; 6.2.7 Examples of Phase Equilibria; 6.3 Nucleation and Growth of Phases; 6.3.1 Thermodynamics of Phase Transformations; 6.3.2 Nucleation; Related Reading; Exercises; 7 Mechanical Properties of Solids-Elasticity; 7.1 Introduction; 7.2 Elasticity Relationships; 7.2.1 True versus Engineering Strain
327   $a7.2.2 Nature of Elasticity and Young's Modulus
330   $aA thorough introduction to fundamental principles and applicationsFrom its beginnings in metallurgy and ceramics, materials science now encompasses such high- tech fields as microelectronics, polymers, biomaterials, and nanotechnology. Electronic Materials Science presents the fundamentals of the subject in a detailed fashion for a multidisciplinary audience. Offering a higher-level treatment than an undergraduate textbook provides, this text benefits students and practitioners not only in electronics and optical materials science, but also in additional cutting-edge fields like polymers a
606   $aElectronics$xMaterials
606   $aElectronic apparatus and appliances$xMaterials
615  0$aElectronics$xMaterials.
615  0$aElectronic apparatus and appliances$xMaterials.
676   $a621.381
700   $aIrene$b Eugene A$0867336
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9910143560503321
996   $aElectronic materials science$91936023
997   $aUNINA