Hoboken, NJ, : John Wiley, 2005

1-280-27602-9

9786610276028

0-470-35362-7

0-471-70854-2

0-471-70853-4

1 online resource (518 p.)

LeeKok Loong <1976->

620.1/8

620.18

Nonferrous metals

Electronic books.

Inglese

Description based upon print version of record.

Includes bibliographical references and index.

STRUCTURE-PROPERTY RELATIONS IN NONFERROUS METALS; CONTENTS; Preface; PART ONE; 1 Crystal and Electronic Structure of Metals; 1.1 Introduction; 1.2 Crystal Structures of the Metallic Elements; 1.3 Exceptions to the Rule of the Metallic Bond; 1.4 Effects of High Pressure on Crystal Structure; 1.5 Effect of Electronic Structure on Crystal Structure; 1.6 Periodic Trends in Material Properties; 2 Defects and Their Effects on Materials Properties; 2.1 Introduction; 2.2 Point Defects; 2.3 Line Defects (Dislocations); 2.4 Planar Defects; 2.5 Volume Defects; 3 Strengthening Mechanisms

3.1 Introduction3.2 Grain Boundary Strengthening; 3.3 Strain Hardening; 3.4 Solid-Solution Hardening; 3.5 Precipitation Hardening (or Age Hardening); 4 Dislocations; 4.1 Introduction; 4.2 Forces on Dislocations; 4.3 Forces Between Dislocations; 4.4 Multiplication of Dislocations; 4.5 Partial Dislocations; 4.6 Slip Systems in Various Crystals; 4.7 Strain Hardening of Single Crystals; 4.8 Thermally Activated Dislocation Motion; 4.9 Interactions of Solute Atoms with Dislocations; 4.10 Dislocation Pile-ups; 5 Fracture and Fatigue; 5.1

Introduction; 5.2 Fundamentals of Fracture; 5.3 Metal Fatigue

6 Strain Rate Effects and Creep6.1 Introduction; 6.2 Yield Point Phenomenon and Strain Aging; 6.3 Ultrarapid Strain Phenomena; 6.4 Creep; 6.5 Deformation Mechanism Maps; 6.6 Superplasticity; 7 Deviations from Classic Crystallinity; 7.1 Introduction; 7.2 Nanocrystalline Metals; 7.3 Amorphous Metals; 7.4 Quasicrystalline Metals; 7.5 Radiation Damage in Metals; 8 Processing Methods; 8.1 Introduction; 8.2 Casting; 8.3 Powder Metallurgy; 8.4 Forming and Shaping; 8.5 Material Removal; 8.6 Joining; 8.7 Surface Modification; 9 Composites; 9.1 Introduction; 9.2 Composite Materials

9.3 Metal Matrix Composites9.4 Manufacturing MMCs; 9.5 Mechanical Properties and Strengthening Mechanisms in MMCs; 9.6 Internal Stresses; 9.7 Stress Relaxation; 9.8 High-Temperature Behavior of MMCs; PART TWO; 10 Li, Na, K, Rb, Cs, and Fr; 10.1 Overview; 10.2 History, Properties, and Applications; 10.3 Sources; 10.4 Structure-Property Relations; 11 Be, Mg, Ca, Sr, Ba, and Ra; 11.1 Overview; 11.2 History and Properties; 11.3 Beryllium; 11.4 Magnesium; 11.5 Heavier Alkaline Metals; 12 Ti, Zr, and Hf; 12.1 Overview; 12.2 Titanium; 12.3 Zirconium; 12.4 Hafnium; 13 V, Nb, and Ta; 13.1 Overview

13.2 History and Properties13.3 Vanadium; 13.4 Niobium; 13.5 Tantalum; 14 Cr, Mo, and W; 14.1 Overview; 14.2 Chromium; 14.3 Molybdenum; 14.4 Tungsten; 15 Mn, Tc, and Re; 15.1 Overview; 15.2 History and Properties; 15.3 Manganese; 15.4 Technetium; 15.5 Rhenium; 16 Co and Ni; 16.1 Overview; 16.2 Cobalt; 16.3 Nickel; 17 Ru, Rh, Pd, Os, Ir, and Pt; 17.1 Overview; 17.2 History, Properties, and Applications; 17.3 Toxicity; 17.4 Sources; 17.5 Structure-Property Relations; 18 Cu, Ag, and Au; 18.1 Overview; 18.2 Copper; 18.3 Silver; 18.4 Gold; 19 Zn, Cd, and Hg; 19.1 Overview; 19.2 Zinc; 19.3 Cadmium

19.4 Mercury

This junior/senior textbook presents fundamental concepts of structure property relations and a description of how these concpets apply to every metallic element except iron. Part One of the book describes general concepts of crystal structure, microstructure and related factors on the mechanical, thermal, magnetic and electronic properties of nonferrous metals, intermetallic compounds and metal matrix composites. Part Two discusses all the nonferrous metallic elements from two perspectives: First it explains how the concepts presented in Part One define the properties of a particular meta