Fernelmont : , : EME, , [2014]

©2014

2-8066-3028-2

1 online resource (147 p.)

610.695

Physicians

Electronic books.

Francese

Description based upon print version of record.

INTRODUCTION; L'anatomopathologiste; L'anesthésiste; Le biologiste clinique; Le cardiologue; Le chercheur; Le chimiothérapeute; Le chirurgien cardiaque; Le chirurgien digestif; Le chirurgien plasticien; Le chirurgien thoracique; Le chirurgien vasculaire; Le dermatologue; L'endocrinologue; Le gastroentérologue; Le gériatre; Le gynécologue; L'hygiéniste; L'infectiologue; L'intensiviste; L'interniste; Le médecin directeur; Le médecin nucléaire; Le néphrologue; Le neurochirurgien; Le neurologue; Le neuropédiatre; Le nutritionniste; L'ophtalmologue; L'ORL; L'orthopédiste; Le pédiatre

Le pneumologueLe psychiatre; Le radiologue; Le rhumatologue; Le stomatologue; L'urgentiste; L'urologue; Conclusion; Du même auteur

Il n'est plus dans les moeurs de s'épancher en vers. Et pourtant poésie a gardé sa fraîcheur. J'ai voulu rendre hommage à d'honnêtes confrères dont certains, disparus, sont pleurés par les leurs. Notre métier n'est plus divisible en deux camps : chirurgie d'un côté, médecine de l'autre. De nouveaux aspects sont nés depuis quelques vingt ans et pour les magnifier, ils ont besoin d'apôtres. Afin de classifier les aimables docteurs, la science typologique est grandement utile. Montrer quelques portraits ne fut pas inutile. Et pour les mieux saisir chacun dans leur métier, j'ai, par quelques croq

Hoboken, : Wiley, 2008

1-282-34294-0

9786612342943

0-470-72712-8

0-470-72713-6

1 online resource (554 p.)

Quantitative software engineering series Microstructural characterization of materials

KaplanWayne D

BrandonD. G

620.1/1299

Electronic books. -- local

Materials -- Microscopy

Microstructure

Materials - Microscopy

Materials Science

Chemical & Materials Engineering

Engineering & Applied Sciences

Electronic books.

Inglese

Description based upon print version of record.

Microstructural Characterization of Materials; Contents; Preface to the Second Edition; Preface to the First Edition; 1 The Concept of Microstructure; 1.1 Microstructural Features; 1.1.1 Structure-Property Relationships; 1.1.2 Microstructural Scale; 1.1.3 Microstructural Parameters; 1.2 Crystallography and Crystal Structure; 1.2.1 Interatomic Bonding in Solids; 1.2.2 Crystalline and Amorphous Phases; 1.2.3 The Crystal Lattice; Summary; Bibliography; Worked Examples; Problems; 2 Diffraction Analysis of Crystal Structure; 2.1 Scattering of Radiation by Crystals

2.1.1 The Laue Equations and Bragg's Law2.1.2 Allowed and Forbidden Reflections; 2.2 Reciprocal Space; 2.2.1 The Limiting Sphere

Construction; 2.2.2 Vector Representation of Bragg's Law; 2.2.3 The Reciprocal Lattice; 2.3 X-Ray Diffraction Methods; 2.3.1 The X-Ray Diffractometer; 2.3.2 Powder Diffraction-Particles and Polycrystals; 2.3.3 Single Crystal Laue Diffraction; 2.3.4 Rotating Single Crystal Methods; 2.4 Diffraction Analysis; 2.4.1 Atomic Scattering Factors; 2.4.2 Scattering by the Unit Cell; 2.4.3 The Structure Factor in the Complex Plane

2.4.4 Interpretation of Diffracted Intensities2.4.5 Errors and Assumptions; 2.5 Electron Diffraction; 2.5.1 Wave Properties of Electrons; 2.5.2 Ring Patterns, Spot Patterns and Laue Zones; 2.5.3 Kikuchi Patterns and Their Interpretation; Summary; Bibliography; Worked Examples; Problems; 3 Optical Microscopy; 3.1 Geometrical Optics; 3.1.1 Optical Image Formation; 3.1.2 Resolution in the Optical Microscope; 3.1.3 Depth of Field and Depth of Focus; 3.2 Construction of the Microscope; 3.2.1 Light Sources and Condenser Systems; 3.2.2 The Specimen Stage; 3.2.3 Selection of Objective Lenses

3.2.4 Image Observation and Recording3.3 Specimen Preparation; 3.3.1 Sampling and Sectioning; 3.3.2 Mounting and Grinding; 3.3.3 Polishing and Etching Methods; 3.4 Image Contrast; 3.4.1 Reflection and Absorption of Light; 3.4.2 Bright-Field and Dark-Field Image Contrast; 3.4.3 Confocal Microscopy; 3.4.4 Interference Contrast and Interference Microscopy; 3.4.5 Optical Anisotropy and Polarized Light; 3.4.6 Phase Contrast Microscopy; 3.5 Working with Digital Images; 3.5.1 Data Collection and The Optical System; 3.5.2 Data Processing and Analysis; 3.5.3 Data Storage and Presentation

3.5.4 Dynamic Range and Digital Storage3.6 Resolution, Contrast and Image Interpretation; Summary; Bibliography; Worked Examples; Problems; 4 Transmission Electron Microscopy; 4.1 Basic Principles; 4.1.1 Wave Properties of Electrons; 4.1.2 Resolution Limitations and Lens Aberrations; 4.1.3 Comparative Performance of Transmission and Scanning Electron Microscopy; 4.2 Specimen Preparation; 4.2.1 Mechanical Thinning; 4.2.2 Electrochemical Thinning; 4.2.3 Ion Milling; 4.2.4 Sputter Coating and Carbon Coating; 4.2.5 Replica Methods; 4.3 The Origin of Contrast; 4.3.1 Mass-Thickness Contrast

4.3.2 Diffraction Contrast and Crystal Lattice Defects

Microstructural characterization is usually achieved by allowing some form of probe to interact with a carefully prepared specimen. The most commonly used probes are visible light, X-ray radiation, a high-energy electron beam, or a sharp, flexible needle. These four types of probe form the basis for optical microscopy, X-ray diffraction, electron microscopy, and scanning probe microscopy.<br /> <br /> <i>Microstructural Characterization of Materials, 2nd Edition</i> is an introduction to the expertise involved in assessing the microstructure of engineering materials and to the experimental met