Verfügbarkeit: Transmission electron microscopy and diffractometry of materials

$Transmission electron microscopy and diffractometry of materials with numerous exercises$

Transmission electron microscopy and diffractometry of materials: with numerous exercises

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Bibliographische Detailangaben
Hauptverfasser:	Fultz, Brent 1955- (VerfasserIn), Howe, James M. 1955- (VerfasserIn)
Format:	Buch
Sprache:	English
Veröffentlicht:	Berlin [u.a.] Springer 2008
Ausgabe:	3. ed.
Schlagworte:	Röntgendiffraktometrie Durchstrahlungselektronenmikroskopie
Online-Zugang:	Inhaltsverzeichnis
Beschreibung:	Literaturangaben
Beschreibung:	XIX, 758 S. zahlr. Ill. und graph. Darst.
ISBN:	9783540738855

Internformat

MARC


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245	1	0	\|a Transmission electron microscopy and diffractometry of materials \|b with numerous exercises \|c Brent Fultz ; James Howe
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Datensatz im Suchindex

_version_	1804137289394159616
adam_text	Titel: Transmission electron microscopy and diffractometry of materials Autor: Fultz, Brent Jahr: 2008 Contents 1. Diffraction and the X-Ray Powder Diffractometer........ 1 1.1 Diffraction............................................. 1 1.1.1 Introduction to Diffraction ........................ 1 1.1.2 Bragg s Law..................................... 3 1.1.3 Strain Effects.................................... 6 1.1.4 Size Effects...................................... 7 1.1.5 A Symmetry Consideration ....................... 9 1.1.6 Momentum and Energy........................... 10 1.1.7 Experimental Methods............................ 10 1.2 The Creation of X-Rays................................. 13 1.2.1 Bremsstrahlung.................................. 14 1.2.2 Characteristic Radiation .......................... 16 1.2.3 Synchrotron Radiation............................ 20 1.3 The X-Ray Powder Diffractometer........................ 23 1.3.1 Practice of X-Ray Generation...................... 23 1.3.2 Goniometer for Powder Diffraction ................. 25 1.3.3 Monochromators, Filters, Mirrors................... 28 1.4 X-Ray Detectors for XRD and TEM...................... 30 1.4.1 Detector Principles............................... 30 1.4.2 Position-Sensitive Detectors ....................... 34 1.4.3 Charge Sensitive Preamplifier...................... 36 1.4.4 Other Electronics................................. 37 1.5 Experimental X-Ray Powder Diffraction Data.............. 38 1.5.1 * Intensities of Powder Diffraction Peaks............ 38 1.5.2 Phase Fraction Measurement ...................... 45 1.5.3 Lattice Parameter Measurement.................... 49 1.5.4 * Refinement Methods for Powder Diffraction Data ... 52 Further Reading............................................ 54 Problems.................................................. 55 2. The TEM and its Optics.................................. 61 2.1 Introduction to the Transmission Electron Microscope....... 61 2.2 Working with Lenses and Ray Diagrams................... 66 2.2.1 Single Lenses.................................... 66 XII Contents ^ . ... 69 2.2.2 Multi-Lens Systems.......................... 2.3 Modes of Operation of a TEM........................... 2.3.1 Dark-Field and Bright-Field Imaging ............... 2.3.2 Selected Area Diffraction.......................... ™ 2.3.3 Convergent-Beam Electron Diffraction.............. 79 2.3.4 High-Resolution Imaging.......................... 8* 2.4 Practical TEM Optics................................... ™ 2.4.1 Electron Guns................................... 85 2.4.2 Illumination Lens Systems......................... 87 2.4.3 Imaging Lens Systems ............................ 88 2.5 Glass Lenses........................................... 2.5.1 Interfaces ....................................... 91 2.5.2 Lenses and Rays................................. 2 2.5.3 Lenses and Phase Shifts........................... 95 2.6 Magnetic Lenses........................................ 97 2.6.1 Focusing........................................ 97 2.6.2 Image Rotation.................................. 99 2.6.3 Pole Piece Gap...................................100 2.7 Lens Aberrations and Other Defects......................102 2.7.1 Spherical Aberration..............................102 2.7.2 Chromatic Aberration............................103 2.7.3 Diffraction.......................................104 2.7.4 Astigmatism.....................................104 2.7.5 Gun Brightness..................................108 2.8 Resolution.............................................110 Further Reading............................................112 Problems..................................................113 3. Scattering................................................119 3.1 Waves and Scattering...................................119 3.1.1 Wavefunctions...................................119 3.1.2 Coherent and Incoherent Scattering.................122 3.1.3 Elastic and Inelastic Scattering.....................123 3.1.4 Wave Amplitudes and Cross-Sections...............124 3.2 X-Ray Scattering .....................................128 3.2.1 Electrodynamics of X-Ray Scattering...............128 3.2.2 * Inelastic Compton Scattering.....................132 3.2.3 X-Ray Mass Attenuation Coefficients...............134 3.3 Coherent Elastic Scattering................... 136 3.3.1 X Born Approximation for Electrons................136 3.3.2 Atomic Form Factors - Physical Picture.............141 3.3.3 X Scattering of Electrons by Model Potentials.......144 q , l tA , * * At°mic Form Factors ~ General Formulation......148 3.4 * Nuclear Scattering.............. 153 3.4.1 Properties of Neutrons............................153 Contents XIII 3.4.2 Time-Varying Potentials and Inelastic Neutron Scat- tering ...........................................155 3.4.3 * Coherent Mössbauer Scattering...................158 Further Reading............................................160 Problems..................................................160 4. Inelastic Electron Scattering and Spectroscopy ...........163 4.1 Inelastic Electron Scattering.............................163 4.2 Electron Energy-Loss Spectrometry (EELS)................165 4.2.1 Instrumentation..................................165 4.2.2 General Features of EELS Spectra..................167 4.2.3 * Fine Structure .................................169 4.3 Plasmon Excitations....................................173 4.3.1 Plasmon Principles...............................173 4.3.2 * Plasmons and Specimen Thickness................175 4.4 Core Excitations .......................................177 4.4.1 Scattering Angles and Energies - Qualitative........177 4.4.2 X Inelastic Form Factor............................180 4.4.3 f * Double-Differential Cross-Section, d2ain/dcf dE ... 184 4.4.4 * Scattering Angles and Energies — Quantitative......186 4.4.5 X * Differential Cross-Section, do-in/d£..............187 4.4.6 X Partial and Total Cross-Sections, 7in..............189 4.4.7 Quantification of EELS Core Edges.................191 4.5 Energy-Filtered TEM Imaging (EFTEM)..................193 4.5.1 Spectrum Imaging................................193 4.5.2 Energy Filters ...................................193 4.5.3 Chemical Mapping with Energy-Filtered Images......196 4.5.4 Chemical Analysis with High Spatial Resolution......197 4.6 Energy Dispersive X-Ray Spectrometry (EDS) .............200 4.6.1 Electron Trajectories Through Materials ............200 4.6.2 Fluorescence Yield................................203 4.6.3 EDS Instrumentation Considerations................205 4.6.4 Thin-Film Approximation.........................208 4.6.5 * ZAF Correction................................211 4.6.6 Artifacts in EDS Measurements....................213 4.6.7 Limits of Microanalysis ...........................215 Further Reading............................................217 Problems..................................................217 5. Diffraction from Crystals.................................223 5.1 Sums of Wavelets from Atoms............................223 5.1.1 Electron Diffraction from a Material............-----224 5.1.2 Wave Diffraction from a Material...................226 5.2 The Reciprocal Lattice and the Laue Condition............230 5.2.1 Diffraction from a Simple Lattice...................230 XIV Contents 001 5.2.2 Reciprocal Lattice................................* 5.2.3 Laue Condition..........................^........23^ 5.2.4 Equivalence of the Laue Condition and Bragg s Law .. 233 5.2.5 Reciprocal Lattices of Cubic Crystals...............234 5.3 Diffraction from a Lattice with a Basis....................235 5.3.1 Structure Factor and Shape Factor .................235 5.3.2 Structure Factor Rules............................237 5.3.3 Symmetry Operations and Forbidden Diffractions .... 242 5.3.4 Superlattice Diffractions...........................243 5.4 Crystal Shape Factor...................................247 5.4.1 Shape Factor of Rectangular Prism.................247 5.4.2 Other Shape Factors..............................252 5.4.3 Small Particles in a Large Matrix...................252 5.5 Deviation Vector (Deviation Parameter)...................256 5.6 Ewald Sphere..........................................257 5.6.1 Ewald Sphere Construction........................257 5.6.2 Ewald Sphere and Bragg s Law.....................259 5.6.3 Tilting Specimens and Tilting Electron Beams.......259 5.7 Laue Zones............................................262 5.8 * Effects of Curvature of the Ewald Sphere................262 Further Reading............................................266 Problems..................................................266 6. Electron Diffraction and Crystallography.................273 6.1 Indexing Diffraction Patterns............................273 6.1.1 Issues in Indexing................................274 6.1.2 Method 1 - Start with Zone Axis...................276 6.1.3 Method 2 - Start with Diffraction Spots.............279 6.2 Stereographic Projections and Their Manipulation..........282 6.2.1 Construction of a Stereographic Projection..........282 6.2.2 Relationship Between Stereographic Projections and Electron Diffraction Patterns...................284 6.2.3 Manipulations of Stereographic Projections..........284 6.3 Kikuchi Lines and Specimen Orientation ..................290 6.3.1 Origin of Kikuchi Lines...........................290 6.3.2 Indexing Kikuchi Lines............................294 6.3.3 Specimen Orientation and Deviation Parameter.....296 6.3.4 The Sign of a...................................299 6.3.5 Kikuchi Maps................. ...... 299 6.4 Double Diffraction............... ...................3Q2 6.4.1 Occurrence of Forbidden Diffractions............ 302 6.4.2 Interactions Between Crystallites 303 6.5 * Convergent-Beam Electron Diffraction 304 6.5.1 Convergence Angle of Incident Electron Beam ....... 306 6.5.2 Determination of Sample Thickness . 307 Contents XV 6.5.3 Measurements of Unit Cell Parameters..............309 6.5.4 X Determination of Point Groups...................314 6.5.5 X Determination of Space Groups...................325 6.6 Further Reading........................................330 Problems..................................................330 7. Diffraction Contrast in TEM Images......................337 7.1 Contrast in TEM Images................................337 7.2 Diffraction from Crystals with Defects ....................339 7.2.1 Review of the Deviation Parameter, s...............339 7.2.2 Atom Displacements, Sr ..........................340 7.2.3 Shape Factor and t...............................341 7.2.4 Diffraction Contrast and {s, Sr, t} .................342 7.3 Extinction Distance.....................................342 7.4 The Phase-Amplitude Diagram...........................345 7.5 Fringes from Sample Thickness Variations.................347 7.5.1 Thickness and Phase-Amplitude Diagrams...........347 7.5.2 Thickness Fringes in TEM Images..................348 7.6 Bend Contours in TEM Images ..........................353 7.7 Diffraction Contrast from Strain Fields....................357 7.8 Dislocations and Burgers Vector Determination ............359 7.8.1 Diffraction Contrast from Dislocation Strain Fields ... 359 7.8.2 The gb Rule for Null Contrast ....................362 7.8.3 Image Position and Dislocation Pairs or Loops.......368 7.9 Semi-Quantitative Diffraction Contrast from Dislocations .... 369 7.10 Weak-Beam Dark-Field (WBDF) Imaging of Dislocations.... 378 7.10.1 Procedure to Make a WBDF Image.................378 7.10.2 Diffraction Condition for a WBDF Image............379 7.10.3 Analysis of WBDF Images.........................380 7.11 Fringes at Interfaces....................................384 7.11.1 Phase Shifts of Electron Wavelets Across Interfaces ... 384 7.11.2 Moire Fringes....................................387 7.12 Diffraction Contrast from Stacking Faults .................391 7.12.1 Kinematical Treatment............................391 7.12.2 Results from Dynamical Theory....................397 7.12.3 Determination of the Intrinsic or Extrinsic Nature of Stacking Faults................................399 7.12.4 Partial Dislocations Bounding the Fault.............399 7.12.5 An Example of a Stacking Fault Analysis............400 7.12.6 Sets of Stacking Faults in TEM Images..............402 7.12.7 Related Fringe Contrast...........................403 7.13 Antiphase (ir) Boundaries and ö Boundaries ...............404 7.13.1 Antiphase Boundaries.............................404 7.13.2 S Boundaries ....................................405 7.14 Contrast from Precipitates and Other Defects..............407 XVI Contents 7.14.1 Vacancies .......................................40^ 7.14.2 Coherent Precipitates.............................408 7.14.3 Semicoherent and Incoherent Particles..............413 Further Reading............................................41^ Problems..................................................414 8. Diffraction Lineshapes....................................423 8.1 Diffraction Line Broadening and Convolution..............423 8.1.1 Crystallite Size Broadening........................424 8.1.2 Strain Broadening................................426 8.1.3 Instrumental Broadening - Convolution.............430 8.2 Fourier Transform Deconvolutions........................433 8.2.1 Mathematical Features............................433 8.2.2 * Effects of Noise on Fourier Transform Deconvolutions 436 8.3 Simultaneous Strain and Size Broadening..................440 8.4 Diffraction Lineshapes from Columns of Crystals...........446 8.4.1 Wavelets from Pairs of Unit Cells in One Column .... 446 8.4.2 A Column Length Distribution.....................448 8.4.3 X Intensity from Column Length Distribution........450 8.5 Comments on Diffraction Lineshapes......................451 Further Reading............................................454 Problems..................................................455 9. Patterson Functions and Diffuse Scattering...............457 9.1 The Patterson Function.................................457 9.1.1 Overview........................................457 9.1.2 Atom Centers at Points in Space...................458 9.1.3 Definition of the Patterson Function................459 9.1.4 Properties of Patterson Functions ..................461 9.1.5 X Perfect Crystals................................463 9.1.6 Deviations from Periodicity and Diffuse Scattering.... 467 9.2 Diffuse Scattering from Atomic Displacements..............469 9.2.1 Uncorrelated Displacements - Homogeneous Disorder . 469 9.2.2 X Temperature..................... 472 9.2.3 * Correlated Displacements - Atomic Size Effects.....477 Diffuse Scattering from Chemical Disorder.................481 9.3.1 Uncorrelated Chemical Disorder - Random Alloys .... 481 9.3.2 X * SRO Parameters........................ 485 9.3.3 X * Patterson Function for Chemical SRO ...... 487 9.3.4 Short-Range Order Diffuse Intensity................488 9.3.5 X * Isotropic Materials......... 488 9.3.6 * Polycrystalline Average and Single Crystal SRO . . . . 490 * Amorphous Materials.............. 491 9-4.1 X One-Dimensional Model.........................491 9.4.2 X Radial Distribution Function.................. 495 9.3 9.4 Contents XVII 9.4.3 X Partial Pair Correlation Functions ................500 9.5 Small Angle Scattering..................................502 9.5.1 Concept of Small Angle Scattering..................502 9.5.2 * Guinier Approximation (small Ak)................504 9.5.3 * Porod Law (large ^life)...........................508 9.5.4 X * Density-Density Correlations (all Ak)............510 Further Reading............................................512 Problems..................................................513 10. High-Resolution TEM Imaging...........................517 10.1 Huygens Principle......................................518 10.1.1 Wavelets from Points in a Continuum...............518 10.1.2 Huygens Principle for a Spherical Wavefront - Fresnel Zones....................................523 10.1.3 X Fresnel Diffraction Near an Edge..................527 10.2 Physical Optics of High-Resolution Imaging................532 10.2.1 X Wavefronts and Fresnel Propagator ............... 532 10.2.2 X Lenses......................................... 534 10.2.3 X Materials...................................... 536 10.3 Experimental High-Resolution Imaging.................... 538 10.3.1 Defocus and Spherical Aberration..................538 10.3.2 X Lenses and Specimens...........................543 10.3.3 Lens Characteristics..............................546 10.4 * Simulations of High-Resolution TEM Images.............555 10.4.1 Principles of Simulations..........................555 10.4.2 Practice of Simulations............................561 10.5 Issues and Examples in High-Resolution TEM Imaging......562 10.5.1 Images of Nanostructures..........................562 10.5.2 Examples of Interfaces............................565 10.5.3 * Specimen and Microscope Parameters.............568 10.5.4 * Some Practical Issues for HRTEM................576 Further Reading............................................580 Problems..................................................581 11. High-Resolution STEM Imaging..........................583 11.1 Characteristics of High-Angle Annular Dark-Field Imaging... 583 11.2 Electron Channeling Along Atomic Columns ..............586 11.2.1 Optical Fiber Analogy............................586 11.2.2 X Critical Angle..................................588 11.2.3 * Tunneling Between Columns.....................589 11.3 Scattering of Channeled Electrons........................591 11.3.1 Elastic Scattering of Channeled Electrons ...........591 11.3.2 * Inelastic Scattering of Channeled Electrons........593 11.4 * Comparison of HAADF and HRTEM Imaging............594 11.5 HAADF Imaging with Atomic Resolution .................595 XVIII Contents 595 11.5.1 * Effect of Defocus............................... 11.5.2 Experimental Examples...........................^ 11.6 * Lens Aberrations and Their Corrections................. «» 11.6.1 Cs Correction with Magnetic Hexapoles.............599 11.6.2 % Higher-Order Aberrations and Instabilities.........602 11.7 Examples of Cs-Corrected Images ........................604 11.7.1 Three-Dimensional Imaging........................605 11.7.2 High Resolution EELS............................606 Further Reading............................................ Problems.................................................. 12. Dynamical Theory........................................611 12.1 Chapter Overview......................................611 12.2 X* Mathematical Features of High-Energy Electrons in a Periodic Potential..................................613 12.2.1 X * Ttle Schrödinger Equation......................613 12.2.2 X Kinematical and Dynamical Theory...............619 12.2.3 * The Crystal as a Phase Grating..................621 12.3 First Approach to Dynamical Theory - Beam Propagation... 623 12.4 X Second Approach to Dynamical Theory - Bloch Waves and Dispersion Surfaces.................................627 12.4.1 Diffracted Beams, {$g}, are Beats of Bloch Waves, {#« }............................627 12.4.2 Crystal Periodicity and Dispersion Surfaces..........633 12.4.3 Energies of Bloch Waves in a Periodic Potential......637 12.4.4 General Two-Beam Dynamical Theory..............640 12.5 Essential Difference Between Kinematical and Dynamical Theories.................................646 12.6 X Diffraction Error, sg, in Two-Beam Dynamical Theory___651 12.6.1 Bloch Wave Amplitudes and Diffraction Error........651 12.6.2 Dispersion Surface Construction....................653 12.7 Dynamical Diffraction Contrast from Crystal Defects .......655 12.7.1 Dynamical Diffraction Contrast Without Absorption .. 655 12.7.2 X * Two-Beam Dynamical Theory of Stacking Fault Contrast.........................660 12.7.3 Dynamical Diffraction Contrast with Absorption.....664 12.8 X * Multi-Beam Dynamical Theories of Electron Diffraction .. 669 Further Reading........................ 672 Problems............................. 672 Bibliography........................... 677 Further Reading..................... 677 References and Figures............... 682 Contents XIX A. Appendix.................................................691 A.l Indexed Powder Diffraction Patterns......................691 A.2 Mass Attenuation Coefficients for Characteristic Kä X-Rays . 692 A.3 Atomic Form Factors for X-Rays.........................693 A.4 X-Ray Dispersion Corrections for Anomalous Scattering.....697 A.5 Atomic Form Factors for 200 keV Electrons and Procedure for Conversion to Other Voltages............698 A.6 Indexed Single Crystal Diffraction Patterns: fee, bec, dc, hep . 703 A.7 Stereographic Projections................................713 A.8 Examples of Fourier Transforms..........................717 A.9 Debye-Waller Factor from Wave Amplitude...............720 A.10 Review of Dislocations .................................721 A.ll TEM Laboratory Exercises..............................728 A. 11.1 Preliminary - JEOL 2000FX Daily Operation........728 A. 11.2 Laboratory 1 - Microscope Procedures and Calibration with Au and M0O3 ................732 A. 11.3 Laboratory 2 - Diffraction Analysis of 9 Precipitates . 735 A.11.4 Laboratory 3 - Chemical Analysis of 6 Precipitates .. 739 A.11.5 Laboratory 4 - Contrast Analysis of Defects.........740 A.12 Fundamental and Derived Constants.....................742 Index.........................................................745 In section titles, the asterisk, *, denotes a more specialized topic. The double dagger, J, warns of a higher level of mathematics, physics, or crys- tallography.
adam_txt	Titel: Transmission electron microscopy and diffractometry of materials Autor: Fultz, Brent Jahr: 2008 Contents 1. Diffraction and the X-Ray Powder Diffractometer. 1 1.1 Diffraction. 1 1.1.1 Introduction to Diffraction . 1 1.1.2 Bragg's Law. 3 1.1.3 Strain Effects. 6 1.1.4 Size Effects. 7 1.1.5 A Symmetry Consideration . 9 1.1.6 Momentum and Energy. 10 1.1.7 Experimental Methods. 10 1.2 The Creation of X-Rays. 13 1.2.1 Bremsstrahlung. 14 1.2.2 Characteristic Radiation . 16 1.2.3 Synchrotron Radiation. 20 1.3 The X-Ray Powder Diffractometer. 23 1.3.1 Practice of X-Ray Generation. 23 1.3.2 Goniometer for Powder Diffraction . 25 1.3.3 Monochromators, Filters, Mirrors. 28 1.4 X-Ray Detectors for XRD and TEM. 30 1.4.1 Detector Principles. 30 1.4.2 Position-Sensitive Detectors . 34 1.4.3 Charge Sensitive Preamplifier. 36 1.4.4 Other Electronics. 37 1.5 Experimental X-Ray Powder Diffraction Data. 38 1.5.1 * Intensities of Powder Diffraction Peaks. 38 1.5.2 Phase Fraction Measurement . 45 1.5.3 Lattice Parameter Measurement. 49 1.5.4 * Refinement Methods for Powder Diffraction Data . 52 Further Reading. 54 Problems. 55 2. The TEM and its Optics. 61 2.1 Introduction to the Transmission Electron Microscope. 61 2.2 Working with Lenses and Ray Diagrams. 66 2.2.1 Single Lenses. 66 XII Contents ^ . . 69 2.2.2 Multi-Lens Systems. 2.3 Modes of Operation of a TEM. 2.3.1 Dark-Field and Bright-Field Imaging . ' 2.3.2 Selected Area Diffraction. ™ 2.3.3 Convergent-Beam Electron Diffraction. 79 2.3.4 High-Resolution Imaging. 8* 2.4 Practical TEM Optics. ™ 2.4.1 Electron Guns. 85 2.4.2 Illumination Lens Systems. 87 2.4.3 Imaging Lens Systems . 88 2.5 Glass Lenses. 2.5.1 Interfaces . 91 2.5.2 Lenses and Rays. "2 2.5.3 Lenses and Phase Shifts. 95 2.6 Magnetic Lenses. 97 2.6.1 Focusing. 97 2.6.2 Image Rotation. 99 2.6.3 Pole Piece Gap.100 2.7 Lens Aberrations and Other Defects.102 2.7.1 Spherical Aberration.102 2.7.2 Chromatic Aberration.103 2.7.3 Diffraction.104 2.7.4 Astigmatism.104 2.7.5 Gun Brightness.108 2.8 Resolution.110 Further Reading.112 Problems.113 3. Scattering.119 3.1 Waves and Scattering.119 3.1.1 Wavefunctions.119 3.1.2 Coherent and Incoherent Scattering.122 3.1.3 Elastic and Inelastic Scattering.123 3.1.4 Wave Amplitudes and Cross-Sections.124 3.2 X-Ray Scattering .128 3.2.1 Electrodynamics of X-Ray Scattering.128 3.2.2 * Inelastic Compton Scattering.132 3.2.3 X-Ray Mass Attenuation Coefficients.134 3.3 Coherent Elastic Scattering. 136 3.3.1 X Born Approximation for Electrons.136 3.3.2 Atomic Form Factors - Physical Picture.141 3.3.3 X Scattering of Electrons by Model Potentials.144 q , l'tA , * * At°mic Form Factors ~ General Formulation.148 3.4 * Nuclear Scattering. 153 3.4.1 Properties of Neutrons.153 Contents XIII 3.4.2 Time-Varying Potentials and Inelastic Neutron Scat- tering .155 3.4.3 * Coherent Mössbauer Scattering.158 Further Reading.160 Problems.160 4. Inelastic Electron Scattering and Spectroscopy .163 4.1 Inelastic Electron Scattering.163 4.2 Electron Energy-Loss Spectrometry (EELS).165 4.2.1 Instrumentation.165 4.2.2 General Features of EELS Spectra.167 4.2.3 * Fine Structure .169 4.3 Plasmon Excitations.173 4.3.1 Plasmon Principles.173 4.3.2 * Plasmons and Specimen Thickness.175 4.4 Core Excitations .177 4.4.1 Scattering Angles and Energies - Qualitative.177 4.4.2 X Inelastic Form Factor.180 4.4.3 f * Double-Differential Cross-Section, d2ain/dcf dE . 184 4.4.4 * Scattering Angles and Energies — Quantitative.186 4.4.5 X * Differential Cross-Section, do-in/d£.187 4.4.6 X Partial and Total Cross-Sections, 7in.189 4.4.7 Quantification of EELS Core Edges.191 4.5 Energy-Filtered TEM Imaging (EFTEM).193 4.5.1 Spectrum Imaging.193 4.5.2 Energy Filters .193 4.5.3 Chemical Mapping with Energy-Filtered Images.196 4.5.4 Chemical Analysis with High Spatial Resolution.197 4.6 Energy Dispersive X-Ray Spectrometry (EDS) .200 4.6.1 Electron Trajectories Through Materials .200 4.6.2 Fluorescence Yield.203 4.6.3 EDS Instrumentation Considerations.205 4.6.4 Thin-Film Approximation.208 4.6.5 * ZAF Correction.211 4.6.6 Artifacts in EDS Measurements.213 4.6.7 Limits of Microanalysis .215 Further Reading.217 Problems.217 5. Diffraction from Crystals.223 5.1 Sums of Wavelets from Atoms.223 5.1.1 Electron Diffraction from a Material.-----224 5.1.2 Wave Diffraction from a Material.226 5.2 The Reciprocal Lattice and the Laue Condition.230 5.2.1 Diffraction from a Simple Lattice.230 XIV Contents 001 5.2.2 Reciprocal Lattice." 5.2.3 Laue Condition.^.23^ 5.2.4 Equivalence of the Laue Condition and Bragg's Law . 233 5.2.5 Reciprocal Lattices of Cubic Crystals.234 5.3 Diffraction from a Lattice with a Basis.235 5.3.1 Structure Factor and Shape Factor .235 5.3.2 Structure Factor Rules.237 5.3.3 Symmetry Operations and Forbidden Diffractions . 242 5.3.4 Superlattice Diffractions.243 5.4 Crystal Shape Factor.247 5.4.1 Shape Factor of Rectangular Prism.247 5.4.2 Other Shape Factors.252 5.4.3 Small Particles in a Large Matrix.252 5.5 Deviation Vector (Deviation Parameter).256 5.6 Ewald Sphere.257 5.6.1 Ewald Sphere Construction.257 5.6.2 Ewald Sphere and Bragg's Law.259 5.6.3 Tilting Specimens and Tilting Electron Beams.259 5.7 Laue Zones.262 5.8 Effects of Curvature of the Ewald Sphere.262 Further Reading.266 Problems.266 6. Electron Diffraction and Crystallography.273 6.1 Indexing Diffraction Patterns.273 6.1.1 Issues in Indexing.274 6.1.2 Method 1 - Start with Zone Axis.276 6.1.3 Method 2 - Start with Diffraction Spots.279 6.2 Stereographic Projections and Their Manipulation.282 6.2.1 Construction of a Stereographic Projection.282 6.2.2 Relationship Between Stereographic Projections and Electron Diffraction Patterns.284 6.2.3 Manipulations of Stereographic Projections.284 6.3 Kikuchi Lines and Specimen Orientation .290 6.3.1 Origin of Kikuchi Lines.290 6.3.2 Indexing Kikuchi Lines.294 6.3.3 Specimen Orientation and Deviation Parameter.296 6.3.4 The Sign of a.299 6.3.5 Kikuchi Maps. . 299 6.4 Double Diffraction. .3Q2 6.4.1 Occurrence of Forbidden Diffractions. 302 6.4.2 Interactions Between Crystallites 303 6.5 * Convergent-Beam Electron Diffraction "" 304 6.5.1 Convergence Angle of Incident Electron Beam . 306 6.5.2 Determination of Sample Thickness . 307 Contents XV 6.5.3 Measurements of Unit Cell Parameters.309 6.5.4 X Determination of Point Groups.314 6.5.5 X Determination of Space Groups.325 6.6 Further Reading.330 Problems.330 7. Diffraction Contrast in TEM Images.337 7.1 Contrast in TEM Images.337 7.2 Diffraction from Crystals with Defects .339 7.2.1 Review of the Deviation Parameter, s.339 7.2.2 Atom Displacements, Sr .340 7.2.3 Shape Factor and t.341 7.2.4 Diffraction Contrast and {s, Sr, t} .342 7.3 Extinction Distance.342 7.4 The Phase-Amplitude Diagram.345 7.5 Fringes from Sample Thickness Variations.347 7.5.1 Thickness and Phase-Amplitude Diagrams.347 7.5.2 Thickness Fringes in TEM Images.348 7.6 Bend Contours in TEM Images .353 7.7 Diffraction Contrast from Strain Fields.357 7.8 Dislocations and Burgers Vector Determination .359 7.8.1 Diffraction Contrast from Dislocation Strain Fields . 359 7.8.2 The gb Rule for Null Contrast .362 7.8.3 Image Position and Dislocation Pairs or Loops.368 7.9 Semi-Quantitative Diffraction Contrast from Dislocations . 369 7.10 Weak-Beam Dark-Field (WBDF) Imaging of Dislocations. 378 7.10.1 Procedure to Make a WBDF Image.378 7.10.2 Diffraction Condition for a WBDF Image.379 7.10.3 Analysis of WBDF Images.380 7.11 Fringes at Interfaces.384 7.11.1 Phase Shifts of Electron Wavelets Across Interfaces . 384 7.11.2 Moire Fringes.387 7.12 Diffraction Contrast from Stacking Faults .391 7.12.1 Kinematical Treatment.391 7.12.2 Results from Dynamical Theory.397 7.12.3 Determination of the Intrinsic or Extrinsic Nature of Stacking Faults.399 7.12.4 Partial Dislocations Bounding the Fault.399 7.12.5 An Example of a Stacking Fault Analysis.400 7.12.6 Sets of Stacking Faults in TEM Images.402 7.12.7 Related Fringe Contrast.403 7.13 Antiphase (ir) Boundaries and ö Boundaries .404 7.13.1 Antiphase Boundaries.404 7.13.2 S Boundaries .405 7.14 Contrast from Precipitates and Other Defects.407 XVI Contents 7.14.1 Vacancies .40^ 7.14.2 Coherent Precipitates.408 7.14.3 Semicoherent and Incoherent Particles.413 Further Reading.41^ Problems.414 8. Diffraction Lineshapes.423 8.1 Diffraction Line Broadening and Convolution.423 8.1.1 Crystallite Size Broadening.424 8.1.2 Strain Broadening.426 8.1.3 Instrumental Broadening - Convolution.430 8.2 Fourier Transform Deconvolutions.433 8.2.1 Mathematical Features.433 8.2.2 * Effects of Noise on Fourier Transform Deconvolutions 436 8.3 Simultaneous Strain and Size Broadening.440 8.4 Diffraction Lineshapes from Columns of Crystals.446 8.4.1 Wavelets from Pairs of Unit Cells in One Column . 446 8.4.2 A Column Length Distribution.448 8.4.3 X Intensity from Column Length Distribution.450 8.5 Comments on Diffraction Lineshapes.451 Further Reading.454 Problems.455 9. Patterson Functions and Diffuse Scattering.457 9.1 The Patterson Function.457 9.1.1 Overview.457 9.1.2 Atom Centers at Points in Space.458 9.1.3 Definition of the Patterson Function.459 9.1.4 Properties of Patterson Functions .461 9.1.5 X Perfect Crystals.463 9.1.6 Deviations from Periodicity and Diffuse Scattering. 467 9.2 Diffuse Scattering from Atomic Displacements.469 9.2.1 Uncorrelated Displacements - Homogeneous Disorder . 469 9.2.2 X Temperature. 472 9.2.3 * Correlated Displacements - Atomic Size Effects.477 Diffuse Scattering from Chemical Disorder.481 9.3.1 Uncorrelated Chemical Disorder - Random Alloys . 481 9.3.2 X * SRO Parameters. 485 9.3.3 X * Patterson Function for Chemical SRO . 487 9.3.4 Short-Range Order Diffuse Intensity.488 9.3.5 X * Isotropic Materials. 488 9.3.6 * Polycrystalline Average and Single Crystal SRO '.'.'.'. 490 * Amorphous Materials. 491 9-4.1 X One-Dimensional Model.491 9.4.2 X Radial Distribution Function.' 495 9.3 9.4 Contents XVII 9.4.3 X Partial Pair Correlation Functions .500 9.5 Small Angle Scattering.502 9.5.1 Concept of Small Angle Scattering.502 9.5.2 * Guinier Approximation (small Ak).504 9.5.3 * Porod Law (large ^life).508 9.5.4 X * Density-Density Correlations (all Ak).510 Further Reading.512 Problems.513 10. High-Resolution TEM Imaging.517 10.1 Huygens Principle.518 10.1.1 Wavelets from Points in a Continuum.518 10.1.2 Huygens Principle for a Spherical Wavefront - Fresnel Zones.523 10.1.3 X Fresnel Diffraction Near an Edge.527 10.2 Physical Optics of High-Resolution Imaging.532 10.2.1 X Wavefronts and Fresnel Propagator . 532 10.2.2 X Lenses. 534 10.2.3 X Materials. 536 10.3 Experimental High-Resolution Imaging. 538 10.3.1 Defocus and Spherical Aberration.538 10.3.2 X Lenses and Specimens.543 10.3.3 Lens Characteristics.546 10.4 * Simulations of High-Resolution TEM Images.555 10.4.1 Principles of Simulations.555 10.4.2 Practice of Simulations.561 10.5 Issues and Examples in High-Resolution TEM Imaging.562 10.5.1 Images of Nanostructures.562 10.5.2 Examples of Interfaces.565 10.5.3 * Specimen and Microscope Parameters.568 10.5.4 * Some Practical Issues for HRTEM.576 Further Reading.580 Problems.581 11. High-Resolution STEM Imaging.583 11.1 Characteristics of High-Angle Annular Dark-Field Imaging. 583 11.2 Electron Channeling Along Atomic Columns .586 11.2.1 Optical Fiber Analogy.586 11.2.2 X Critical Angle.588 11.2.3 * Tunneling Between Columns.589 11.3 Scattering of Channeled Electrons.591 11.3.1 Elastic Scattering of Channeled Electrons .591 11.3.2 * Inelastic Scattering of Channeled Electrons.593 11.4 * Comparison of HAADF and HRTEM Imaging.594 11.5 HAADF Imaging with Atomic Resolution .595 XVIII Contents 595 11.5.1 * Effect of Defocus. 11.5.2 Experimental Examples.^ 11.6 * Lens Aberrations and Their Corrections. «» 11.6.1 Cs Correction with Magnetic Hexapoles.599 11.6.2 % Higher-Order Aberrations and Instabilities.602 11.7 Examples of Cs-Corrected Images .604 11.7.1 Three-Dimensional Imaging.605 11.7.2 High Resolution EELS.606 Further Reading. Problems. 12. Dynamical Theory.611 12.1 Chapter Overview.611 12.2 X* Mathematical Features of High-Energy Electrons in a Periodic Potential.613 12.2.1 X * Ttle Schrödinger Equation.613 12.2.2 X Kinematical and Dynamical Theory.619 12.2.3 * The Crystal as a Phase Grating.621 12.3 First Approach to Dynamical Theory - Beam Propagation. 623 12.4 X Second Approach to Dynamical Theory - Bloch Waves and Dispersion Surfaces.627 12.4.1 Diffracted Beams, {$g}, are Beats of Bloch Waves, {#« }.627 12.4.2 Crystal Periodicity and Dispersion Surfaces.633 12.4.3 Energies of Bloch Waves in a Periodic Potential.637 12.4.4 General Two-Beam Dynamical Theory.640 12.5 Essential Difference Between Kinematical and Dynamical Theories.646 12.6 X Diffraction Error, sg, in Two-Beam Dynamical Theory_651 12.6.1 Bloch Wave Amplitudes and Diffraction Error.651 12.6.2 Dispersion Surface Construction.653 12.7 Dynamical Diffraction Contrast from Crystal Defects .655 12.7.1 Dynamical Diffraction Contrast Without Absorption . 655 12.7.2 X * Two-Beam Dynamical Theory of Stacking Fault Contrast.660 12.7.3 Dynamical Diffraction Contrast with Absorption.664 12.8 X * Multi-Beam Dynamical Theories of Electron Diffraction . 669 Further Reading. 672 Problems. 672 Bibliography. 677 Further Reading. 677 References and Figures. 682 Contents XIX A. Appendix.691 A.l Indexed Powder Diffraction Patterns.691 A.2 Mass Attenuation Coefficients for Characteristic Kä X-Rays . 692 A.3 Atomic Form Factors for X-Rays.693 A.4 X-Ray Dispersion Corrections for Anomalous Scattering.697 A.5 Atomic Form Factors for 200 keV Electrons and Procedure for Conversion to Other Voltages.698 A.6 Indexed Single Crystal Diffraction Patterns: fee, bec, dc, hep . 703 A.7 Stereographic Projections.713 A.8 Examples of Fourier Transforms.717 A.9 Debye-Waller Factor from Wave Amplitude.720 A.10 Review of Dislocations .721 A.ll TEM Laboratory Exercises.728 A. 11.1 Preliminary - JEOL 2000FX Daily Operation.728 A. 11.2 Laboratory 1 - Microscope Procedures and Calibration with Au and M0O3 .732 A. 11.3 Laboratory 2 - Diffraction Analysis of 9' Precipitates . 735 A.11.4 Laboratory 3 - Chemical Analysis of 6' Precipitates . 739 A.11.5 Laboratory 4 - Contrast Analysis of Defects.740 A.12 Fundamental and Derived Constants.742 Index.745 In section titles, the asterisk, "*," denotes a more specialized topic. The double dagger, "J," warns of a higher level of mathematics, physics, or crys- tallography.
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spelling	Fultz, Brent 1955- Verfasser (DE-588)122354796 aut Transmission electron microscopy and diffractometry of materials with numerous exercises Brent Fultz ; James Howe 3. ed. Berlin [u.a.] Springer 2008 XIX, 758 S. zahlr. Ill. und graph. Darst. txt rdacontent n rdamedia nc rdacarrier Literaturangaben Röntgendiffraktometrie (DE-588)4336833-5 gnd rswk-swf Durchstrahlungselektronenmikroskopie (DE-588)4215608-7 gnd rswk-swf Durchstrahlungselektronenmikroskopie (DE-588)4215608-7 s Röntgendiffraktometrie (DE-588)4336833-5 s 1\p DE-604 DE-604 Howe, James M. 1955- Verfasser (DE-588)122354818 aut HBZ Datenaustausch application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=016258192&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis 1\p cgwrk 20201028 DE-101 https://d-nb.info/provenance/plan#cgwrk
spellingShingle	Fultz, Brent 1955- Howe, James M. 1955- Transmission electron microscopy and diffractometry of materials with numerous exercises Röntgendiffraktometrie (DE-588)4336833-5 gnd Durchstrahlungselektronenmikroskopie (DE-588)4215608-7 gnd
subject_GND	(DE-588)4336833-5 (DE-588)4215608-7
title	Transmission electron microscopy and diffractometry of materials with numerous exercises
title_auth	Transmission electron microscopy and diffractometry of materials with numerous exercises
title_exact_search	Transmission electron microscopy and diffractometry of materials with numerous exercises
title_exact_search_txtP	Transmission electron microscopy and diffractometry of materials with numerous exercises
title_full	Transmission electron microscopy and diffractometry of materials with numerous exercises Brent Fultz ; James Howe
title_fullStr	Transmission electron microscopy and diffractometry of materials with numerous exercises Brent Fultz ; James Howe
title_full_unstemmed	Transmission electron microscopy and diffractometry of materials with numerous exercises Brent Fultz ; James Howe
title_short	Transmission electron microscopy and diffractometry of materials
title_sort	transmission electron microscopy and diffractometry of materials with numerous exercises
title_sub	with numerous exercises
topic	Röntgendiffraktometrie (DE-588)4336833-5 gnd Durchstrahlungselektronenmikroskopie (DE-588)4215608-7 gnd
topic_facet	Röntgendiffraktometrie Durchstrahlungselektronenmikroskopie
url	http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=016258192&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA
work_keys_str_mv	AT fultzbrent transmissionelectronmicroscopyanddiffractometryofmaterialswithnumerousexercises AT howejamesm transmissionelectronmicroscopyanddiffractometryofmaterialswithnumerousexercises

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