ABE-IPSABE HOLDINGABE BOOKS
English Polski
On-line access

Bookstore

0.00 PLN
Bookshelf (0) 
Your bookshelf is empty
Physical Metallurgy: Principles and Design

Physical Metallurgy: Principles and Design

Authors
Publisher Taylor & Francis Ltd
Year 15/05/2018
Pages 476
Version hardback
Readership level General/trade
Language English
ISBN 9781138627680
Categories Life sciences: general issues, Environmental science, engineering & technology
$177.15 (with VAT)
787.50 PLN / €168.84 / £146.57
Qty:
Delivery to United States

check shipping prices
Product to order
Delivery 5-6 weeks
Add to bookshelf

Book description

Physical metallurgy is one of the main fields of metallurgical science dealing with the development of the microstructure of metals in order to achieve desirable properties required in technological applications. Physical Metallurgy: Principles and Design focuses on the processing-structure-properties triangle as it applies to metals and alloys. It introduces the fundamental principles of physical metallurgy and the design methodologies for alloys and processing. The first part of the book discusses the structure and change of structure through phase transformations. The latter part of the books deals with plastic deformation, strengthening mechanisms, and mechanical properties as they relate to structure. The book also includes a chapter on physical metallurgy of steels and concludes by discussing the computational tools, involving computational thermodynamics and kinetics, to perform alloy and process design. "The new textbook by Professor Haidemenopoulos serves as a comprehensive introduction to the physical metallurgy of metals. The phenomena are described in a conceptional and demonstrative manner; a link to real materials application is elaborated for many possible applications. It is especially worth mentioning that the consequent numerical description of the fundamental design principles of metals offers the entrance for physics-based modelling of materials and processes."
-Wolfgang Bleck, RWTH Aachen University, Germany





"The book by Haidemenopolous is an up-to-date book on the physical metallurgy of metals. It covers the well-known topics of phase transformations under equilibrium and non-equilibrium conditions, as well as the strengthening mechanism and the way it can be used during metal production or treatment. The last chapter on Alloy Design is a nice integration of the concepts explained and takes the book from the level of explaining what is known already to the level of (the start of) a toolbox to redesign new alloys based on conceptual thinking."
-Sybrand van der Zwaag, Delft University of Technology, Netherlands


"Although this specialised text is - first and foremost - aimed at upwardly mobile students studying with a materials science department, the author cordially invites others to read this book and categorically states (page 2) that his aim is to help readers (of other persuasions) to understand the behaviour of metals subjected to mechanical and/or thermomechanical loads.... [a] useful well-organised authoritative book. All who are studying strength of materials as a core subject will also find much in this book that is directly relevant to their studies."


--Peter C. Gasson,CEng, MIMechE, FRAeS, The Aeronautical Journal, October 2020

Physical Metallurgy: Principles and Design

Table of contents

Chapter 1 Introduction





1.1 What is Physical Metallurgy





1.2 The Aim of the Book





1.3 Who Should Read this Book





1.4 Book Structure





1.5 How to Read the Book











Chapter 2 Structure of Metals





2.1 Introduction





2.2 Crystalline vs. Amorphous Materials





2.3 The Crystal Lattice





2.4 The Crystal Structure of Metals





2.5 Allotropy





2.6 Crystal Structure Effects





2.7 Solid Solutions





2.8 Intermetallic Compounds and Intermediate Phases





2.9 A First Look at the Microstructure of Alloys





2.10 Thermodynamics and Kinetics of Structure





2.11 Synopsis





2.12 Review Questions











Chapter 3 Structural Imperfections





3.1 Introduction





3.2 Point Defects





3.3 Linear Imperfections - Dislocations





3.4 Interfaces





3.5 Synopsis





3.6 Review Questions











Chapter 4 Alloy Thermodynamics and Phase Diagrams





4.1 Introduction





4.2 Free Energy of Pne-component Systems (Pure Metals)





4.3 Free Energy of Solid Solutions





4.4 Chemical Potential and Thermodynamic Equilibrium





4.5 The Gibbs Phase Rule





4.6 Equilibrium Phase Diagrams in Binary Systems





4.7 Examples of Phase Diagrams





4.8 Case study: Solder Alloys - The Pb-Sn Phase Diagram





4.9 Synopsis





4.10 Review Questions











Chapter 5 Diffusion





5.1 Introduction





5.2 Diffusion Mechanisms





5.3 Fick's First Law of Diffusion - The Diffusion Coefficient





5.4 Random Walk and Diffusion





5.5 Fick's Second Law of Diffusion





5.6 Temperature Dependence of Diffusion





5.7 Thermodynamics and Diffusion





5.8 Substitutional Diffusion





5.9 Irreversible Thermodynamics and Diffusion





5.10 Effects of Diffusion





5.11 Analytical Solutions to the Diffusion Equation





5.12 Numerical Methods - Computational Kinetics





5.13 Synopsis





5.14 Review Questions











Chapter 6 Phase Transformations





6.1 Introduction





6.2 Nucleation and Growth Transformations (NGT)





6.3 Nucleation





6.4 Growth





6.5 Overall rate of Concurrent Nucleation and Growth





6.6 Coarsening





6.7 Continuous Transformations





6.8 Martensitic Transformations





6.9 Effects of Phase Transformations





6.10 Synopsis





6.11 Review Questions











Chapter 7 Plastic Deformation and Annealing





7.1 Introduction





7.2 Mechanisms of Plastic Deformation





7.3 Deformation of Single Crystals by Slip





7.4 Deformation in Polycrystals





7.5 Strain Hardening





7.6 Mechanical Twinning





7.7 Annealing





7.8 Texture in Polycrystalline Metals





7.9 Synopsis





7.10 Review Questions











Chapter 8 Strengthening Mechanisms





8.1 Introduction





8.2 Slip as a Thermally Activated Process





8.3 Overview of Strengthening Mechanisms





8.4 Lattice Resistance





8.5 Solid Solution Strengthening





8.6 Grain Boundary Strengthening





8.7 Precipitation Strengthening





8.8 Implications of Strengthening Mechanisms





8.9 Synopsis





8.10 Review Questions











Chapter 9 Fracture, Fatigue and Creep of Metals





9.1 Introduction - Mechanical Behavior of Metals





9.2 Fracture





9.3 Fatigue





9.4 Creep





9.5 Synopsis





9.6 Review Questions











Chapter 10 Physical Metallurgy of Steels





10.1 Introduction





10.2 Phases in Steels





10.3 The Fe-C phase Diagram





10.4 Alloying Elements in Steels





10.5 Phase Transformations in Steels





10.6 Hardenability





10.7 Tempering of Martensite





10.8 Heat Treatment of Steel





10.9 Case Studies in Steels





10.10Synopsis





10.11Review Questions











Chapter 11 Alloy Design





11.1 Introduction





11.2 The Alloyneering Methodology for Alloy Design





11.3 Simulation Framework





11.4 Simulation Examples





11.5 Alloy Design: Medium Mn Steels





11.6 Process Design: Multi-pass Hot Rolling of Steels





11.7 Synopsis





Index

We also recommend books

Strony www Białystok Warszawa
801 777 223