Description
Density Functional Theory: Fundamental Theory, Key Methods, and Applications provides a thorough and detailed explanation and overview of this important computational quantum mechanical modeling method and its applications. The book's chapters are structured to be easier to understand and more accessible to the target audience. Split into three distinct sections, it examines foundational knowledge surrounding DFT, covering key concepts such as the Thomas-Fermi model and Hohenberg-Kohn-Sham theory, exchange-correlation functionals, the advantages and disadvantages of DFT compared to MO theory, and other methods before exploring areas of future DFT development.The second section then examines practical methods and approaches for DFT, looking at the types of density functionals such as LSDA, GGA and meta-GGA functionals, hybrid functionals, DFTB methods, dispersion corrected functionals, Time-Dependent DFT, and the Plane-wave approach. It also looks at relations between DFT and ab initio molecular dynamics and the QM/MM approach. The final section then focuses on applications and some useful case studies of use of DFT in different areas, whilst weighing up strengths and weaknesses in such applications.- Provides a comprehensive and broad, yet detailed overview of theory, methods and practical applications of Density Functional Theory (DFT) geared chiefly towards theoretical (computational) and physical chemistry- Meets the need for an up-to-date work focused more heavily on chemistry applications of DFT than most existing literature- Designed to be more accessible to late undergraduate, graduate, and postdoc researchers getting to grips with DFT, where existing literature has mostly been quite impenetrable and very specific- Incorporates case studies of practical applications of DFT and objectively weighs up the advantages and disadvantages and recent and future potential advances
Table of Contents
Part I: Foundational Knowledge1. History of the DFT concept: inspiring ideas and development2. DFT concept: Thomas-Fermi model and Hohenberg-Kohn-Sham theory, their comparisons and applicability3. Exchange-correlation functionals: review, history, areas of applications4. Novel and recently designed DFT functionals, their advantages and applications5. Advantages and disadvantages of DFT compared to MO theory and other methods: scalability, ways to improve, areas of applications6. Density matrix functional theory7. Machine-learning of DFT functionals8. Linear scaling of DFT methods9. Future DFT development: theory, conceptual applications, computational improvementPart II: Methods and Approaches10. Local-spin density approximation: history, present state, applications11. GGA, meta-GGA, and hybrid functionals: development, applications, perspectives12. Semiempirical DFT: DFTB, parametrization, present state, and perspectives13. Dispersion corrected functionals: development, future perspectives, applications14. Time-Dependent DFT: development, future perspectives, applications15. Plane-wave approach16. Relations between DFT and ab initio molecular dynamics17. Relations between DFT and QM/MM approach19. DFT methods use and peculiarities for vibrational (phonons) calculations20. DFT methods use and peculiarities for transition state search21. DFT methods use and peculiarities for various spectral properties investigations22. DFT methods use and peculiarities for study of different spin-states23. DFT methods use and peculiarities for chemical reactions studies24. DFT methods use and peculiarities for solid-state studiesPart III: Applications and Case Studies25. Areas of good and poor performance of DFT: various multiplicities, weak interactions, loosely bound electrons, structures, chemical bonding26. DFT in studies of complexes/systems with hydrogen bonding: history, present state, and perspectives, functionals used, ways to improve the performance27. DFT in studies of complexes/systems with dispersion interactions: history, present state, and perspectives – complexes of graphene etc., functionals used, ways to improve the performance28. DFT for reactivity studies/conceptual DFT: history, current state, and perspectives29. DFT in design of pharmacologically active compounds: organic compounds, organometallic compounds, approaches used, perspectives and improvement routes30. DFT applications in transition metal studies: history, present state, perspectives, functionals employed, issues and the ways to overcome them31. DFT for design of compounds for alternative/sustainable energetics: history, present state, approach used and perspectives32. DFT in design of anticorrosive compounds: current state, perspectives, approaches33. DFT in engineering of crystals and related systems34. DFT in design of semiconductors and oxides35. DFT in catalysis studies: history, current situation, future, approaches used, problems and ways to overcome them36. DFT in design of solid-state catalysts37. DFT in studies of biologically relevant systems: history, present state, restrictions and problems encountered, future perspectives38. DFT methods for large systems
