Review:
The first advanced text/reference to cover the essential theoretical aspects of materials modeling
From the Back Cover:
[ELSEVIER Academic Press LOGO]
Technology: Engineering. General
Computational Materials Engineering
An Introduction to Microstructure Evolution
K. G. F. Janssens
Paul Scherrer Institute, Villigen, Switzerland
KEY FEATURES
·Balanced coverage of fundamentals of materials modeling, as well as more advanced aspects of modeling, such as modeling at all scales from the atomic to the molecular to the macro-material
·Concise, yet rigorous mathematical coverage of such analytical tools as the Potts type Monte Carlo method, cellular automata, phase field, dislocation dynamics and Finite Element Analysis in statistical and analytical modeling
·Companion web site will offer ample workable programs, along with suggested projects, resources for further reading, and useful classroom exercises
Computational Materials Engineering is a single source of the major elements that make up contemporary computer modeling of materials characteristics and behavior. This is the first advanced text/reference to cover the essential theoretical aspects of materials modeling, with a particular emphasis on polycrystalline materials—including the physical, thermal and chemical parameters—and the mathematical tools used to perform simulations, as well as specific applications to modeling real materials. Readers will first gain an understanding of the underlying statistical and analytical tools that are the basis for modeling complex material interactions, including an understanding of computational thermodynamics and molecular kinetics. Then, they will learn to use various modeling systems such as Finite Element Analysis and Finite Difference Analysis to generate mathematical representations of material processes. Finally, the book will offer its readers a variety of algorithms to use in solving typical modeling problems so that the theory presented herein can be put to real-world use.
Contents:
1 Introduction; 2 Basic Thermodynamics 21; 3 Monte Carlo Potts Model; 4 Cellular Automata; 5 Solid-state diffusion; 6 Modeling precipitation; 7 Phase-field Modeling; 8 Discrete Dislocations; 9 FEM
Related titles:
Ashby: Materials: Engineering, Science, Processing and Design, 2007, ISBN: 978-0-75068391-3
Ashby: Materials Selection in Mechanical Design, 3rd Edition, 2005, ISBN: 978-0-7506-6168-3
Ohring: Materials Science of Thin Films, 2nd edition, Academic Press,2001, ISBN: 978- 0-12-524975-1|[ELSEVIER Academic Press LOGO]
Technology: Engineering. General
Computational Materials Engineering
An Introduction to Microstructure Evolution
K. G. F. Janssens
Paul Scherrer Institute, Villigen, Switzerland
KEY FEATURES
·Balanced coverage of fundamentals of materials modeling, as well as more advanced aspects of modeling, such as modeling at all scales from the atomic to the molecular to the macro-material
·Concise, yet rigorous mathematical coverage of such analytical tools as the Potts type Monte Carlo method, cellular automata, phase field, dislocation dynamics and Finite Element Analysis in statistical and analytical modeling
·Companion web site will offer ample workable programs, along with suggested projects, resources for further reading, and useful classroom exercises
Computational Materials Engineering is a single source of the major elements that make up contemporary computer modeling of materials characteristics and behavior. This is the first advanced text/reference to cover the essential theoretical aspects of materials modeling, with a particular emphasis on polycrystalline materials—including the physical, thermal and chemical parameters—and the mathematical tools used to perform simulations, as well as specific applications to modeling real materials. Readers will first gain an understanding of the underlying statistical and analytical tools that are the basis for modeling complex material interactions, including an understanding of computational thermodynamics and molecular kinetics. Then, they will learn to use various modeling systems such as Finite Element Analysis and Finite Difference Analysis to generate mathematical representations of material processes. Finally, the book will offer its readers a variety of algorithms to use in solving typical modeling problems so that the theory presented herein can be put to real-world use.
Contents:
1 Introduction; 2 Basic Thermodynamics 21; 3 Monte Carlo Potts Model; 4 Cellular Automata; 5 Solid-state diffusion; 6 Modeling precipitation; 7 Phase-field Modeling; 8 Discrete Dislocations; 9 FEM
Related titles:
Ashby: Materials: Engineering, Science, Processing and Design, 2007, ISBN: 978-0-75068391-3
Ashby: Materials Selection in Mechanical Design, 3rd Edition, 2005, ISBN: 978-0-7506-6168-3
Ohring: Materials Science of Thin Films, 2nd edition, Academic Press,2001, ISBN: 978- 0-12-524975-1
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