Details
Conceptual Density Functional Theory
Towards a New Chemical Reactivity Theory1. Aufl.
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268,99 € |
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| Verlag: | Wiley-VCH |
| Format: | |
| Veröffentl.: | 31.03.2022 |
| ISBN/EAN: | 9783527829927 |
| Sprache: | englisch |
| Anzahl Seiten: | 720 |
DRM-geschütztes eBook, Sie benötigen z.B. Adobe Digital Editions und eine Adobe ID zum Lesen.
Beschreibungen
<b>Conceptual Density Functional Theory</b> <p><b>A unique resource that combines experimental and theoretical qualitative computing methods for a new foundation of chemical reactivity</b> <p>This two-volume reference book shows how conceptual density functional theory can reconcile empirical observations within silico calculations using density functional theory, molecular orbital theory, and valence bond theory. The ability to predict properties like electronegativity, acidity/basicity, strong covalent and weak intermolecular interactions as well as chemical reactivity makes DFT directly applicable to almost all problems in applied chemistry, from synthetic chemistry to catalyst design and materials characterization. <p>Edited by one of the most recognized experts in the field and contributed to by a panel of international experts, the work addresses topics such as: <ul><li>Qualitative methods that are capable of rationalizing chemical concepts derived from theory and computation</li> <li>Fundamental concepts like the computation of chemical bonding, weak interactions, and reactivity</li> <li>Computational approaches for chemical concepts in excited states, extended systems, and time-dependent processes</li></ul> <p>Theoretical chemists and physicists, as well as those applying theoretical calculations to empirical problems, will be able to use this book to gain unique insight into how theory intersects with experimental data in the field of qualitative computation.
<p>PART I. FOUNDATIONS<br> Historic Overview<br> Basic Functions of CDFT<br> Basic Formulas of CDFT<br> Basic Principles of CDFT<br> <p>PART II. EXTENSIONS<br> Excited state CDFT<br> Degenerate State CDFT<br> Spin CDFT<br> Temperature Dependent CDFT<br> Time-dependent CDFT<br> Regioselectivity in CDFT<br> Charge Transfer in CDFT<br> Action Flux<br> Mechanic Force<br> HSAB & Beyond<br> Information-Theoretic Approach<br> The Linear Response Function and Alchemical Method<br> Valence State Concepts and their Implications for Conceptual DFT<br> Chemical Information<br> Molecular Shape<br> Bridging Conceptual Density Functional and Valence Bond Theories<br> <p>PART III. APPLICATIONS<br> Chemical Bonding <br> Molecular Acidity, PCET, and Metal Specificity <br> Reaction Mechanism<br> Polar Cycloaddition Reactions: Reactivity and Site Selectivity<br> Polymorphism<br> Variation in Reactivity on Hydrogen Storage<br> The Fukui Function in Extended Systems: Theory and Applications<br> Fermi Softness in Surface Catalysis<br> ABEEM Polarizable Force Field<br> Charge Transfer and Polarization in Force Fields<br> <p>PART IV. IMPLEMENTATIONS<br> Realization of Conceptual Density Functional Theory and Information-Theoretic Approach in the Multiwfn Program<br> ChemTools: Gain Chemical Insight from Quantum Chemistry Calculations<br>
<p><b><i>Dr. Shubin Liu </B>is a Senior Computational Scientist at the Research Computing Center and an Adjunct Professor at the Department of Chemistry, University of North Carolina at Chapel Hill. He obtained his Ph.D. degree with Robert G. Parr in 1996 and postdoctoral training with Weitao Yang of Duke University. He has been an independent researcher since 2000, focusing on developing a chemical reactivity theory using density functional theory language. Dr. Shubin Liu has authored over 200 peer-reviewed publications and is recognized in the field by various scientific awards including the Wiley-IJQC Young Investigator Award.</i></p>
<p><b>A unique resource that combines experimental and theoretical qualitative computing methods for a new foundation of chemical reactivity</b></p> <p>This two-volume reference book shows how conceptual density functional theory can reconcile empirical observations within silico calculations using density functional theory, molecular orbital theory, and valence bond theory. The ability to predict properties like electronegativity, acidity/basicity, strong covalent and weak intermolecular interactions as well as chemical reactivity makes DFT directly applicable to almost all problems in applied chemistry, from synthetic chemistry to catalyst design and materials characterization. <p>Edited by one of the most recognized experts in the field and contributed to by a panel of international experts, the work addresses topics such as: <ul><li>Qualitative methods that are capable of rationalizing chemical concepts derived from theory and computation</li> <li>Fundamental concepts like the computation of chemical bonding, weak interactions, and reactivity</li> <li>Computational approaches for chemical concepts in excited states, extended systems, and time-dependent processes</li></ul> <p>Theoretical chemists and physicists, as well as those applying theoretical calculations to empirical problems, will be able to use this book to gain unique insight into how theory intersects with experimental data in the field of qualitative computation.
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