Book contents
- Computational Design of Engineering Materials
- Computational Design of Engineering Materials
- Copyright page
- Dedication
- Contents
- Foreword
- Preface
- Acknowledgments
- 1 Introduction
- 2 Fundamentals of Atomistic Simulation Methods
- 3 Fundamentals of Mesoscale Simulation Methods
- 4 Fundamentals of Crystal Plasticity Finite Element Method
- 5 Fundamentals of Computational Thermodynamics and the CALPHAD Method
- 6 Fundamentals of Thermophysical Properties
- 7 Case Studies on Steel Design
- 8 Case Studies on Light Alloy Design
- 9 Case Studies on Superalloy Design
- 10 Case Studies on Cemented Carbide Design
- 11 Case Studies on Hard Coating Design
- 12 Case Studies on Energy Materials Design
- 13 Summary and Future Development of Materials Design
- Book part
- Index
- Plate Section (PDF Only)
- References
1 - Introduction
Published online by Cambridge University Press: 29 June 2023
Book contents
- Computational Design of Engineering Materials
- Computational Design of Engineering Materials
- Copyright page
- Dedication
- Contents
- Foreword
- Preface
- Acknowledgments
- 1 Introduction
- 2 Fundamentals of Atomistic Simulation Methods
- 3 Fundamentals of Mesoscale Simulation Methods
- 4 Fundamentals of Crystal Plasticity Finite Element Method
- 5 Fundamentals of Computational Thermodynamics and the CALPHAD Method
- 6 Fundamentals of Thermophysical Properties
- 7 Case Studies on Steel Design
- 8 Case Studies on Light Alloy Design
- 9 Case Studies on Superalloy Design
- 10 Case Studies on Cemented Carbide Design
- 11 Case Studies on Hard Coating Design
- 12 Case Studies on Energy Materials Design
- 13 Summary and Future Development of Materials Design
- Book part
- Index
- Plate Section (PDF Only)
- References
Summary
The advance of human civilization with materials development from the Stone Age to the Information Age is the starting point of Chapter 1, highlighting significant roles of computational design of materials. Important terms (model, simulation, database, and materials design) used in computational materials science are defined. The past and present development of computational design of materials is then introduced. A few milestones for alloy design, such as the Hume–Rothery rule, the Phase Computation (PHACOMP) method, and the calculation of phase diagrams (CALPHAD) approach, are highlighted. The past two-decade focus on three aspects in computational design of materials (multiscale/multilevel modeling methodologies, simulation software, and scientific database) in the core of the Materials Genome Initiative is emphasized. A general framework of materials design is demonstrated with two flowcharts: through-process simulation of Al alloys during heat treatment, and the three stages for the development of engineering materials. The two-part structure of the book – fundamentals and case studies – is explained.
Keywords
- Type
- Chapter
- Information
- Computational Design of Engineering MaterialsFundamentals and Case Studies, pp. 1 - 11Publisher: Cambridge University PressPrint publication year: 2023
References
Ashby, M. F., Shercliff, H., and Cebon, D. (2019) Materials: Engineering, Science, Processing and Design, fourth edition. Oxford: Butterworth-Heinemann (Elsevier).Google Scholar
Boesch, W. J., and Slaney, J. S. (1964) Preventing sigma phase embrittlement in nickel base superalloys. Metal Progress, 86, 109–111.Google Scholar
Bozzolo, G., Noebe, R. D., and Abel, P. B. (2007) Applied Computational Materials Modeling: Theory, Simulation and Experiment. Berlin and Heidelberg: Springer Science & Business Media, LLC.CrossRefGoogle Scholar
Chang, T. K. (1958) A critical interpretation of “liu-ch’i’”. Journal of Tsinghua University, 4(2), 159–166.Google Scholar
Da Silva, L. F. M. (ed), (2019) Materials Design and Applications II, volume 98. New York: Springer.CrossRefGoogle Scholar
Du, Y., Li, K., Zhao, P. Z, et al. (2017) Integrated computational materials engineering (ICME) for developing aluminum alloys. Journal of Aeronautical Materials, 37(1), 1–17.Google Scholar
Gottstein, G. (2007) Integral Materials Modeling. Weinheim: Wiley-VCH Verlag GmbH & Co. KGaA.CrossRefGoogle Scholar
Horstemeyer, M. F. (2012) Integrated Computational Materials Engineering (ICME) for Metals: Using Multiscale Modeling to Invigorate Engineering Design with Science. John Wiley & Sons.CrossRefGoogle Scholar
Hume-Rothery, W. (1967) Phase Stability in Metals and Alloys. Edited by Rudman, P. S., Stringer, J., and Jaffee., R. I. New York: McGraw-Hill, 3.Google Scholar
ICME (2008) Integrated Computational Materials Engineering: A Transformational Discipline for Improved Competitiveness and National Security. Committee on Integrated Computational Materials Engineering and National Materials Advisory Board. Washington: National Academies Press.Google Scholar
ICME (2013) Integrated Computational Materials Engineering (ICME): Implementing ICME in the Aerospace, Automotive, and Maritime Industries. Pittsburgh: The Minerals, Metals and Materials Society.Google Scholar
Kampmann, R., and Wagner, R. (1984) Kinetics of precipitation in metastable binary alloys – theory and application to Cu-1.9 at % Ti and Ni-14 at % Al. In Haasen, P., Gerold, V., Wagner, R., and Ashby, M. F. (eds), Decomposition of Alloys: The Early Stages: Proceedings of the 2nd Acta-Scripta Metallurgica Conference. Sonnenberg, Germany, 19-23/09/1983. Oxford: Pergamon, 91–103.Google Scholar
Kaufman, L., and Ågren, J. (2014) CALPHAD, first and second generation – birth of the materials genome. Scripta Materialia, 45, 3–6.CrossRefGoogle Scholar
Kaufman, L., and Bernstein, H. (1970) Computer Calculation of Phase Diagrams. New York: Academic Press.Google Scholar
LeSar, R. (2013) Introduction to Computational Materials Science: Fundamentals to Applications. Cambridge: Cambridge University Press.CrossRefGoogle Scholar
Li, B., Du, Y., Qiu, L. C., et al. (2018) Shallow talk about integrated computational materials engineering and Materials Genome Initiative: Ideas and Practice. Materials China, 37(7), 506–525.Google Scholar
Lukas, H. L., Fries, S. G., and Sundman, B. (2007) Computational Thermodynamics: The Calphad Method. Cambridge: Cambridge University Press.CrossRefGoogle Scholar
Matsugi, K., Murata, Y., Morinaga, M., and Yukawa, N. (1993) An electronic approach to alloy design and its application to Ni-based single-crystal superalloys. Materials Science and Engineering A, 172(1), 101–110.CrossRefGoogle Scholar
McDowell, D. L., Panchal, J. H., Choi, H. J., Seepersad, C. C., Allen, J. K., and Mistree, F. (2010) Integrated Design of Multiscale, Multifunctional Materials and Products. Amsterdam: Elsevier.Google Scholar
Meijering, J. L. (1950) Segregation in regular ternary solutions: Part I. Philips Research Reports, 5, 333–356.Google Scholar
MGI (2011) Materials Genome Initiative for Global Competitiveness. Washington: National Science and Technology Council, Executive Office of the President, USA.Google Scholar
Morinaga, M., Murata, Y., and Yukawa, H. (2003) An electronic approach to materials design. Journal of Materials Science and Technology, 19, 73–76.Google Scholar
Olson, G. B. (1997) Computational design of hierarchically structured materials. Science, 277, 1237–1242.CrossRefGoogle Scholar
Olson, G. B. (2000) Pathways of discovery: designing a new materials world. Science, 288, 993–998.CrossRefGoogle Scholar
Qiu, L. C., Du, Y., Wang, S. Q., et al. (2019) Through-process modeling and experimental verification of titanium carbonitride coating prepared by moderate temperature chemical vapor deposition. Surface & Coating Technology, 359, 278–288.CrossRefGoogle Scholar
Raabe, D., Roters, F., Barlat, F., and Chen, L.-Q. (2004) Continuum Scale Simulation of Engineering Materials: Fundamentals – Microstructures – Process Applications. Indianapolis: John Wiley & Sons.CrossRefGoogle Scholar
Rajan, K. (2008) Learning from systems biology: an “omics” approach to materials design. JOM, 60, 53–55.CrossRefGoogle Scholar
Saito, T. (1999) Computational Materials Design. Springer Series in Materials Science, 34. Berlin and Heidelberg: Springer-Verlag Berlin Heidelberg GmbH.CrossRefGoogle Scholar
Schmid-Fetzer, R. (2015) Progress in thermodynamic database development for ICME of Mg alloys. In Manuel, M. V., Singh, A., Alderman, M., and Neelameggham, N. R. (eds), Magnesium Technology 2015, The Minerals, Metals and Materials Society (TMS), Pittsburgh, 283–287.Google Scholar
Shin, D., and Saal, J. (eds) (2018) Computational Materials System Design. Cham: Springer.CrossRefGoogle Scholar
van Laar, J. J. (1908) Melting or solidification curves in binary system. Zeitschrift für Physikalische Chemie, 63, 216–253.Google Scholar