MATERIALS SCIENCE AND ENGINEERING: A FIRST COURSEThis well-established and widely adopted book, now in its Sixth Edition, provides a thorough analysis of the subject in an easy-to-read style. It analyzes, systematically and logically, the basic concepts and their applications to enable the students to comprehend the subject with ease. The book begins with a clear exposition of the background topics in chemical equilibrium, kinetics, atomic structure and chemical bonding. Then follows a detailed discussion on the structure of solids, crystal imperfections, phase diagrams, solid-state diffusion and phase transformations. This provides a deep insight into the structural control necessary for optimizing the various properties of materials. The mechanical properties covered include elastic, anelastic and viscoelastic behaviour, plastic deformation, creep and fracture phenomena. The next four chapters are devoted to a detailed description of electrical conduction, superconductivity, semiconductors, and magnetic and dielectric properties. The final chapter on ‘Nanomaterials’ is an important addition to the sixth edition. It describes the state-of-art developments in this new field. This eminently readable and student-friendly text not only provides a masterly analysis of all the relevant topics, but also makes them comprehensible to the students through the skillful use of well-drawn diagrams, illustrative tables, worked-out examples, and in many other ways. The book is primarily intended for undergraduate students of all branches of engineering (B.E./B.Tech.) and postgraduate students of Physics, Chemistry and Materials Science. KEY FEATURES • All relevant units and constants listed at the beginning of each chapter • A note on SI units and a full table of conversion factors at the beginning • A new chapter on ‘Nanomaterials’ describing the state-of-art information • Examples with solutions and problems with answers • About 350 multiple choice questions with answers |
Contents
1 | |
2 Equilibrium and Kinetics | 9 |
3 Crystal Geometry and Structure Determination | 23 |
4 Atomic Structure and Chemical Bonding | 53 |
5 Structure of Solids | 81 |
6 Crystal Imperfections | 120 |
7 Phase Diagrams | 148 |
8 Diffusion in Solids | 178 |
14 Conductors and Resistors | 332 |
15 Semiconductors | 355 |
16 Magnetic Materials | 393 |
17 Dielectric Materials | 412 |
18 Nanomaterials | 427 |
Appendix IProperties of Elements | 451 |
Appendix IIProperties of Engineering Materials | 454 |
455 | |
9 Phase Transformations | 201 |
10 Elastic Anelastic and Viscoelastic Behaviour | 238 |
11 Plastic Deformation and Creep in Crystalline | 260 |
12 Fracture | 298 |
13 Oxidation and Corrosion | 315 |
ATOMIC AND IONIC RADII | 464 |
CRYSTAL STRUCTURES OF THEELEMENTS | 465 |
Back cover | 466 |
Common terms and phrases
alloy aluminium anions Answer applied atoms austenite bond energy Bragg angle brittle Burgers vector carbon cation cementite close packed composition concentration conduction band configuration constant cooling copper covalent covalent bonds crack crystal structure crystalline cubic curve decreases dielectric diffusion direction ductile edge dislocation elastic electrical elements enthalpy entropy equilibrium eutectic example extrinsic semiconductor FCC crystal ferrite ferromagnetic fraction fracture free electron free energy function grain boundaries heat hydrogen impurity increases interface interstitial ionic ions iron kJ mol–1 lattice parameter liquid magnetic martensite material melting point metals metre microstructure molecules neighbours nucleation orbitals oxidation oxygen particles pearlite phase diagram plastic deformation polarization polymers potential energy radius ratio reaction region resistance room temperature semiconductor shear shown in Fig silicon slip plane solid Solution space lattice steel strain strength stress superconductor surface Table tensile thermal energy transformation unit cell valence band wavelength