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A State-of-the-Art Guide to the Mechanics of Asphalt ConcreteMechanics of Asphalt systematically covers both the fundamentals and most recent developments in applying rational mechanics, microstructure characterization methods, and numerical tools to understand the behavior of asphalt concrete (AC). The book describes the essential mathematics, mechanics, and numerical techniques required for comprehending advanced modeling and simulation of asphalt materials and asphalt pavements. Filled with detailed illustrations, this authoritative volume provides rational mechanisms to guide the development of best practices in mix design, construction methods, and performance evaluation of asphalt concrete.
Mechanics of Asphalt covers:
Fundamentals for mathematics and continuum mechanics
Mechanical properties of constituents, including binder, aggregates, mastics, and mixtures
Microstructure characterization
Experimental methods to characterize the heterogeneous strain field
Mixture theory and micromechanics applications
Fundamentals of phenomenological models
Multiscale modeling and moisture damage
Models for asphalt concrete, including viscoplasticity, viscoplasticity with damage, disturbed state mechanics model, and fatigue failure criteria
Finite element method, boundary element method, and discrete element method
Digital specimen and digital test-integration of microstructure and simulation
Simulation of asphalt compaction
Characterization and modeling of anisotropic properties of asphalt concrete
Contents
Acknowledgments; Chapter 1. Introduction and Fundamentals for Mathematics and Continuum Mechanics; Chapter 2. Mechanical Properties of Constituents; Chapter 3. Microstructure Characterization; Chapter 4. Experimental Methods to Characterize the Heterogeneous Strain Field; Chapter 5. Mixture Theory and Micromechanics Applications; Chapter 6. Fundamentals of Phenomenological Models; Chapter 7. Models for Asphalt Concrete; Chapter 8. Finite Element Method and Boundary Element Method; Chapter 9. Applications of Discrete Element Method; Chapter 10. Digital Specimen and Digital Test-Integration of Microstructure into Simulation; Chapter 11. Simulation of Asphalt Compaction; Chapter 12. Characterization and Modeling Anisotropic Properties of Asphalt Concrete; Chapter 13. Multiscale Modeling and Moisture Damage; Appendix 1. Eshelby's Tensor (S) for Special Cases; Appendix 2. Laplace Transform; Appendix 3. Isotropic Elastostatics Fundamental Solution; Index
