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1.

図書

図書
H. Bakker ... [et al.] ; Herausgeber, H. Mehrer
出版情報: Berlin ; Tokyo : Springer-Verlag, c1990  xiv, 747 p. ; 28 cm
シリーズ名: Landolt-Börnstein Zahlenwerte und Funktionen aus Naturwissenschaften und Technik, Neue Serie / Gesamtherausgabe, K.-H. Hellwege ; Gruppe 3 . Kristal- und Festkörperphysik ; Bd. 26
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Introductory material
General introduction / H. Mehrer1:
Fick's laws, flux of particles, isotropic and anisotropic diffusion / 1.1:
Solutions of diffusion equations for constant diffusivity / 1.2:
Diffusion equation for concentration dependent diffusivity / 1.3:
The various diffusion coefficients / 1.4:
Atomistic mechanisms of diffusion / 1.5:
Methods of measuring diffusion coefficients / 1.6:
Diffusion along dislocations, grain boundaries and on surfaces / 1.7:
Temperature dependence of diffusion / 1.8:
Mass- and pressure dependence of diffusion / 1.9:
Diffusion in amorphous alloys / 1.10:
Further readings / 1.11:
References for 1 / 1.12:
Self-diffusion in solid metallic elements / N. Stolica ; N.A. Stolwijk2:
Introduction / 2.1:
The self-diffusion tables / 2.2:
Figures for 2
References for 2 / 2.3:
Diffusion of impurities in solid metallic elements / A.D. Leclaire ; G. Neumann3:
The impurity diffusion tables / 3.1:
Figures for 3
References for 3 / 3.3:
Self-diffusion in homogeneous binary alloys and intermediate phases / H. Bakker4:
Figures for 4
References for 4
Chemical diffusion in inhomogeneous binary alloys / G.E. Murch ; C.M. Bruff5:
Chemical diffusion tables / 5.1:
Figures for 5
References for 5 / 5.3:
Diffusion in ternary alloys / M.A. Dayananda6:
Generalized forms of Fick's law, ternary interdiffusion and intrinsic diffusion coefficients / 6.1:
Solutions of diffusion equations for constant ternary interdiffusion coefficients / 6.2:
Concentration-dependent ternary interdiffusion coefficients / 6.3:
Determination of ternary intrinsic diffusion coefficients with inert markers / 6.4:
Tracer diffusion coefficients / 6.5:
Use of the tables and figures / 6.7:
The diffusion tables / 6.8:
Figures for 6
References for 6 / 6.9:
General remarks / J. Horvath7:
The effect of different production methods / 7.2:
Methods of diffusion investigations on amorphous alloys / 7.3:
Diffusion tables for amorphous alloys / 7.4:
Figures for 7
References for 7 / 7.6:
Diffusion of C, N, and O metals / 8:
Diffusion tables for C, N, and O in metals / 8.1:
Figures for 8
References for 8 / 8.3:
The diffusion of H, D, and T in solid metals / G.V. Kidson9:
Methods of measurernents of diffusion coefficients of hydrogen in metals / 9.1:
Diffusion tables for H, D, and T in solid metals / 9.3:
Figures for 9
References for 9 / 9.5:
Mass and pressure dependence of diffusion in solid metals and alloys / 10:
Mass dependence of diffusion / 10.1:
The isotope effect tables for diffusion in solid metallic elements / 10.2:
Isotope effect tables for diffusion in binary alloys / 10.3:
Figures for 10.2 and 10.3
References for 10.2 and 10.3
Pressure dependence of diffusion / 10.4:
Pressure effect tables for diffusion in solid elements / 10.5:
Pressure effect tables for diffusion in homogeneous binary alloys / 10.6:
Pressure effect tables for interdiffusion in binary alloys / 10.7:
Figures for 10.5 - 10.7
References for 10.4 - 10.7
Diffusion in dislocations / 11:
Methods of measurement / 11.1:
Presentation of results / 11.3:
References for 11 / 11.4:
Grain and interphase boundary diffusion / I. Kaur ; W. Gust12:
Data for grain and interphase boundary diffusion / 12.1:
Figures for 12
References for 12 / 12.3:
Surface diffusion on metals / H.P. Bonzel13:
Mechanisms of surface diffusion / 13.1:
Anisotropy of surface diffusion / 13.3:
Cluster surface diffusion / 13.4:
Adsorbate-modified surface self-diffusion / 13.5:
Concentration dependence in surface hetero-diffusion / 13.6:
Measuring techniques / 13.7:
Systematics of surface diffusion coefficients / 13.8:
Commentary to tables / 13.9:
Surface diffusion tables / 13.10:
Figures for 13
Special references: review articles / 13.11:
References for 13 / 13.12:
Introductory material
General introduction / H. Mehrer1:
Fick's laws, flux of particles, isotropic and anisotropic diffusion / 1.1:
2.

図書

図書
H.メーラー著 ; 藤川辰一郎訳
出版情報: 東京 : 丸善出版, 2012.6  xviii, 676p ; 24 cm
シリーズ名: Springer university textbooks
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3.

図書

図書
Helmut Mehrer
出版情報: Berlin : Springer, c2007  xix, 651 p. ; 25 cm
シリーズ名: Springer series in solid-state sciences ; 155
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History and Bibliography of Diffusion / 1:
Pioneers and Landmarks of Diffusion / 1.1:
References
Bibliography of Solid-State Diffusion / 1.2:
Fundamentals of Diffusion / Part I:
Continuum Theory of Diffusion / 2:
Fick's Laws in Isotropic Media / 2.1:
Fick's First Law / 2.1.1:
Equation of Continuity / 2.1.2:
Fick's Second Law - the 'Diffusion Equation' / 2.1.3:
Diffusion Equation in Various Coordinates / 2.2:
Fick's Laws in Anisotropic Media / 2.3:
Solutions of the Diffusion Equation / 3:
Steady-State Diffusion / 3.1:
Non-Steady-State Diffusion in one Dimension / 3.2:
Thin-Film Solution / 3.2.1:
Extended Initial Distribution and Constant Surface Concentration / 3.2.2:
Method of Laplace Transformation / 3.2.3:
Diffusion in a Plane Sheet - Separation of Variables / 3.2.4:
Radial Diffusion in a Cylinder / 3.2.5:
Radial Diffusion in a Sphere / 3.2.6:
Point Source in one, two, and three Dimensions / 3.3:
Random Walk Theory and Atomic Jump Process / 4:
Random Walk and Diffusion / 4.1:
A Simplified Model / 4.1.1:
Einstein-Smoluchowski Relation / 4.1.2:
Random Walk on a Lattice / 4.1.3:
Correlation Factor / 4.1.4:
Atomic Jump Process / 4.2:
Point Defects in Crystals / 5:
Pure Metals / 5.1:
Vacancies / 5.1.1:
Divacancies / 5.1.2:
Determination of Vacancy Properties / 5.1.3:
Self-Interstitials / 5.1.4:
Substitutional Binary Alloys / 5.2:
Vacancies in Dilute Alloys / 5.2.1:
Vacancies in Concentrated Alloys / 5.2.2:
Ionic Compounds / 5.3:
Frenkel Disorder / 5.3.1:
Schottky Disorder / 5.3.2:
Intermetallics / 5.4:
Semiconductors / 5.5:
Diffusion Mechanisms / 6:
Interstitial Mechanism / 6.1:
Collective Mechanisms / 6.2:
Vacancy Mechanism / 6.3:
Divacancy Mechanism / 6.4:
Interstitialcy Mechanism / 6.5:
Interstitial-Substitutional Exchange Mechanisms / 6.6:
Correlation in Solid-State Diffusion / 7:
Vacancy Mechanism of Self-diffusion / 7.1:
A 'Rule of Thumb' / 7.3.1:
Vacancy-tracer Encounters / 7.3.2:
Spatial and Temporal Correlation / 7.3.3:
Calculation of Correlation Factors / 7.3.4:
Correlation Factors of Self-diffusion / 7.4:
Vacancy-mediated Solute Diffusion / 7.5:
Face-Centered Cubic Solvents / 7.5.1:
Body-Centered Cubic Solvents / 7.5.2:
Diamond Structure Solvents / 7.5.3:
Concluding Remarks / 7.6:
Dependence of Diffusion on Temperature and Pressure / 8:
Temperature Dependence / 8.1:
The Arrhenius Relation / 8.1.1:
Activation parameters - Examples / 8.1.2:
Pressure Dependence / 8.2:
Activation Volumes of Self-diffusion / 8.2.1:
Activation Volumes of Solute Diffusion / 8.2.2:
Activation Volumes of Ionic Crystals / 8.2.3:
Correlations between Diffusion and Bulk Properties / 8.3:
Melting Properties and Diffusion / 8.3.1:
Activation Parameters and Elastic Constants / 8.3.2:
Use of Correlations / 8.3.3:
Isotope Effect of Diffusion / 9:
Single-jump Mechanisms / 9.1:
Isotope Effect Experiments / 9.2:
Interdiffusion and Kirkendall Effect / 10:
Interdiffusion / 10.1:
Boltzmann Transformation / 10.1.1:
Boltzamann-Matano Method / 10.1.2:
Sauer-Freise Method / 10.1.3:
Intrinsic Diffusion and Kirkendall Effect / 10.2:
Darken Equations / 10.3:
Darken-Manning Equations / 10.4:
Microstructural Stability of the Kirkendall Plane / 10.5:
Diffusion and External Driving Forces / 11:
Overview / 11.1:
Fick's Equations with Drift / 11.2:
Nernst-Einstein Relation / 11.3:
Nernst-Einstein Relation for Ionic Conductors and Haven Ratio / 11.4:
Nernst-Planck Equation - Interdiffusion in Ionic Crystals / 11.5:
Nernst-Planck Equation versus Darken Equation / 11.6:
Irreversible Thermodynamics and Diffusion / 12:
General Remarks / 12.1:
Phenomenological Equations of Isothermal Diffusion / 12.2:
Tracer Self-Diffusion in Element Crystals / 12.2.1:
Diffusion in Binary Alloys / 12.2.2:
The Phenomenological Coefficients / 12.3:
Phenomenological Coefficients, Tracer Diffusivities, and Jump Models / 12.3.1:
Sum Rules - Relations between Phenomenological Coefficients / 12.3.2:
Experimental Methods / Part II:
Direct Diffusion Studies / 13:
Direct versus Indirect Methods / 13.1:
The Various Diffusion Coefficients / 13.2:
Tracer Diffusion Coefficients / 13.2.1:
Interdiffusion and Intrinsic Diffusion Coefficients / 13.2.2:
Tracer Diffusion Experiments / 13.3:
Profile Analysis by Serial Sectioning / 13.3.1:
Residual Activity Method / 13.3.2:
Isotopically Controlled Heterostructures / 13.4:
Secondary Ion Mass Spectrometry (SIMS) / 13.5:
Electron Microprobe Analysis (EMPA) / 13.6:
Auger-Electron Spectroscopy (AES) / 13.7:
Ion-beam Analysis: RBS and NRA / 13.8:
Mechanical Spectroscopy / 14:
Anelasticity and Internal Friction / 14.1:
Techniques of Mechanical Spectroscopy / 14.3:
Examples of Diffusion-related Anelasticty / 14.4:
Snoek Effect (Snoek Relaxation) / 14.4.1:
Zener Effect (Zener Relaxation) / 14.4.2:
Gorski Effect (Gorski Relaxation) / 14.4.3:
Mechanical Loss in Ion-conducting Glasses / 14.4.4:
Magnetic Relaxation / 14.5:
Nuclear Methods / 15:
Nuclear Magnetic Relaxation (NMR) / 15.1:
Fundamentals of NMR / 15.2.1:
Direct Diffusion Measurement by Field-Gradient NMR / 15.2.2:
NMR Relaxation Methods / 15.2.3:
Mossbauer Spectroscopy (MBS) / 15.3:
Quasielastic Neutron Scattering (QENS) / 15.4:
Examples of QENS studies / 15.4.1:
Advantages and Limitations of MBS and QENS / 15.4.2:
Electrical Methods / 16:
Impedance Spectroscopy / 16.1:
Spreading Resistance Profiling / 16.2:
Diffusion in Metallic Materials / Part III:
Self-diffusion in Metals / 17:
Cubic Metals / 17.1:
FCC Metals - Empirical Facts / 17.2.1:
BCC Metals - Empirical Facts / 17.2.2:
Monovacancy Interpretation / 17.2.3:
Mono-and Divacancy Interpretation / 17.2.4:
Hexagonal Close-Packed and Tetragonal Metals / 17.3:
Metals with Phase Transitions / 17.4:
Diffusion of Interstitial Solutes in Metals / 18:
'Heavy' Interstitial Solutes C, N, and O / 18.1:
Interstitial Diffusion in Dilute Interstial Alloys / 18.1.1:
Hydrogen Diffusion in Metals / 18.2:
Examples of Hydrogen Diffusion / 18.2.1:
Non-Classical Isotope Effects / 18.2.4:
Diffusion in Dilute Substitutional Alloys / 19:
Diffusion of Impurities / 19.1:
'Normal' Impurity Diffusion / 19.1.1:
Impurity Diffusion in Al / 19.1.2:
Impurity Diffusion in 'Open' Metals - Dissociative Mechanism / 19.2:
Solute Diffusion and Solvent Diffusion in Alloys / 19.3:
Diffusion in Binary Intermetallics / 20:
Influence of Order-Disorder Transitions / 20.1:
B2 Intermetallics / 20.3:
Diffusion Mechanisms in B2 Phases / 20.3.1:
Example B2 NiAl / 20.3.2:
Example B2 Fe-Al / 20.3.3:
Uniaxial Intermetallics / 20.4:
Laves Phases / 20.6.1:
Diffusion in Quasicrystalline Alloys / 20.8:
General Remarks on Quasicrystals / 21.1:
Diffusion Properties of Quasicrystals / 21.2:
Icosahedral Quasicrystals / 21.2.1:
Decagonal Quasicrystals / 21.2.2:
Diffusion in Semiconductors / Part IV:
General Remarks on Semiconductors / 22:
'Semiconductor Age' and Diffusion / 22.1:
Specific Features of Semiconductor Diffusion / 22.2:
Self-diffusion in Elemental Semiconductors / 23:
Intrinsic Point Defects and Diffusion / 23.1:
Germanium / 23.2:
Silicon / 23.3:
Foreign-Atom Diffusion in Silicon and Germanium / 24:
Solubility and Site Occupancy / 24.1:
Diffusivities and Diffusion Modes / 24.2:
Interstitial Diffusion / 24.2.1:
Dopant Diffusion / 24.2.2:
Diffusion of Hybrid Foreign Elements / 24.2.3:
Self-and Foreign Atom Diffusion - a Summary / 24.3:
Interstitial-Substitutional Diffusion / 25:
Combined Dissociative and Kick-out Diffusion / 25.1:
Diffusion Limited by the Flow of Intrinsic Defects / 25.1.1:
Diffusion Limited by the Flow of Interstitial Solutes / 25.1.2:
Numerical Analysis of an Intermediate Case / 25.1.3:
Kick-out Mechanism / 25.2:
Basic Equations and two Solutions / 25.2.1:
Examples of Kick-Out Diffusion / 25.2.2:
Dissociative Mechanism / 25.3:
Basic Equations / 25.3.1:
Examples of Dissociative Diffusion / 25.3.2:
Diffusion and Conduction in Ionic Materials / Part V:
Ionic Crystals / 26:
Point Defects in Ionic Crystals / 26.1:
Intrinsic Defects / 26.2.1:
Extrinsic Defects / 26.2.2:
Methods for the Study of Defect and Transport Properties / 26.3:
Alkali Halides / 26.4:
Defect Motion, Tracer Self-diffusion, and Ionic Conduction / 26.4.1:
Example NaCl / 26.4.2:
Common Features of Alkali Halides / 26.4.3:
Silver Halides AgCl and AgBr / 26.5:
Self-diffusion and Ionic Conduction / 26.5.1:
Doping Effects / 26.5.2:
Fast Ion Conductors / 27:
Fast Silver-Ion Conductors / 27.1:
AgI and related Simple Anion Structures / 27.1.1:
Stabilised Zirconia and related Oxide Ion Conductors / 27.1.2:
Perovskite Oxide Ion Conductors / 27.4:
Sodium ?-Alumina and related Materials / 27.5:
Lithium Ion Conductors / 27.6:
Polymer Electrolytes / 27.7:
Diffusion in Glasses / Part VI:
The Glassy State / 28:
What is a Glass? / 28.1:
Volume-Temperature Diagram / 28.2:
Temperature-Time-Transformation Diagram / 28.3:
Glass Families / 28.4:
Diffusion in Metallic Glasses / 29:
Structural Relaxation and Diffusion / 29.1:
Diffusion Properties of Metallic Glasses / 29.3:
Diffusion and Viscosity in Class-forming Alloys / 29.4:
Diffusion and Ionic Conduction in Oxide Glasses / 30:
Gas Permeation / 30.1:
Examples of Diffusion and Ionic Conduction / 30.4:
Diffusion along High-Diffusivity Paths and in Nanomaterials / Part VII:
High-diffusivity Paths in Metals / 31:
Diffusion Spectrum / 31.1:
Empirical Rules for Grain-Boundary Diffusion / 31.3:
Lattice Diffusion and Microstructural Defects / 31.4:
Grain-Boundary Diffusion / 32:
Grain Boundaries / 32.1:
Low-and High-Angle Grain Boundaries / 32.2.1:
Special High-Angle Boundaries / 32.2.2:
Diffusion along an Isolated Boundary (Fisher Model) / 32.3:
Diffusion Kinetics in Polycrystals / 32.4:
Type A Kinetics Regime / 32.4.1:
Type B Kinetics Regime / 32.4.2:
Type C Kinetics Regime / 32.4.3:
Grain Boundary Diffusion and Segregation / 32.5:
Atomic Mechanisms of Grain-Boundary Diffusion / 32.6:
Dislocation Pipe Diffusion / 33:
Disloction Pipe Model / 33.1:
Solutions for Mean Thin Layer Concentrations / 33.2:
Diffusion in Nanocrystalline Materials / 34:
Synthesis of Nancrystalline Materials / 34.1:
Powder Processing / 34.2.1:
Heavy Plastic Deformation / 34.2.2:
Chemical and Related Synthesis Methods / 34.2.3:
Devitrification of Amorphous Precursors / 34.2.4:
Diffusion in Poly - and Nanocrystals / 34.3:
Grain Size and Diffusion Regimes / 34.3.1:
Effective Diffusivities in Poly - and Nanocrystals / 34.3.2:
Diffusion in Nanocrystalline Metals / 34.4:
Structural Relaxation and Grain Growth / 34.4.1:
Nanomaterials with Bimodal Grain Structure / 34.4.3:
Grain Boundary Triple Junctions / 34.4.4:
Diffusion and Ionic Conduction in Nanocrystalline Ceramics / 34.5:
Index
History and Bibliography of Diffusion / 1:
Pioneers and Landmarks of Diffusion / 1.1:
References
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