
Atomistic Computer Simulations Are Often At The Heart Of Modern Attempts To Predict And Understand The Physical Properties Of Real Materials, Including The Vast Domain Of Metals And Alloys. Historically, Highly Simplified Empirical Potentials Have Been Used To Provide The Interatomic Forces Needed To Perform Such Simulations, But True Predictive Power In These Materials Emanates From Fundamental Quantum Mechanics. In Metals And Alloys Especially, A Viable Path Forward To The Vastly Larger Length And Time Scales Offered By Empirical Potentials, While Retaining The Predictive Power Of Quantum Mechanics, Is To Course-grain The Underlying Electronic Structure Of The Material And Systematically Derive Quantum-based Interatomic Potentials From First-principles. This Book Spans The Entire Process From Foundation In Fundamental Theory, To The Development Of Accurate Quantum-based Potentials For Real Materials, To The Wide-spread Application Of The Potentials To The Atomistic Simulation Of Structural, Thermodynamic, Defect And Mechanical Properties Of Metals And Alloys.--back Cover.
This text investigates the methodology for deriving quantum-based interatomic potentials from first-principles to bridge the gap between fundamental electronic structure and large-scale atomistic simulations in metals and alloys. Dr. John A. Moriarty presents a systematic framework for coarse-graining electronic structure to maintain predictive accuracy while extending simulation capabilities to larger length and time scales. The book synthesizes theoretical foundations with practical development techniques to address the limitations of traditional empirical potentials in materials science.
What You Will Find
Scope Limits
Experts recognize this work as a rigorous technical resource for researchers engaged in computational materials science. Readers frequently note the high level of mathematical and theoretical density required to fully grasp the derivation processes presented.
Page Count:
0
Publication Date:
2023-01-01
Publisher:
New York, NY : Oxford University Press,
ISBN-10:
0191861227
ISBN-13:
9780191861222
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