Handbook of Computational Chemistry

1. Front Matter

   Pages i-xx

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2. From Quantum Theory to Computational Chemistry. A Brief Account of Developments

   • Lucjan Piela

   Pages 1-12

3. The Position of the Clamped Nuclei Electronic Hamiltonian in Quantum Mechanics

   • Brian Sutcliffe, R. Guy Woolley

   Pages 13-54

4. Remarks on Wave Function Theory and Methods

   • Dariusz Kedziera, Anna Kaczmarek-Kedziera

   Pages 55-93

5. Directions for Use of Density Functional Theory: A Short Instruction Manual for Chemists

   • Heiko Jacobsen, Luigi Cavallo

   Pages 95-133

6. Introduction to Response Theory

   • Thomas Bondo Pedersen

   Pages 135-156

7. Intermolecular Interactions

   • Alston J. Misquitta

   Pages 157-193

8. Molecular Dynamics Simulation: From “Ab Initio” to “Coarse Grained”

   • Chris Lorenz, Nikos L Doltsinis

   Pages 195-238

9. Statistical Mechanics of Force-Induced Transitions of Biopolymers

   • Sanjay Kumar

   Pages 239-258

10. Molecular Mechanics: Method and Applications

    • Valeri Poltev

    Pages 259-291

11. Molecular Structure and Vibrational Spectra

    • Jon Baker

    Pages 293-359

12. Molecular Electric, Magnetic, and Optical Properties

    • Michał Jaszuński, Antonio Rizzo, Kenneth Ruud

    Pages 361-441

13. Weak Intermolecular Interactions: A Supermolecular Approach

    • Mark Waller, Stefan Grimme

    Pages 443-466

14. Chemical Reactions: Thermochemical Calculations

    • John D. Watts

    Pages 467-482

15. Calculation of Excited States: Molecular Photophysics and Photochemistry on Display

    • Luis Serrano-Andrés, Juan José Serrano-Pérez

    Pages 483-560

16. Solvent Effects in Quantum Chemistry

    • Gerald Monard, Jean-Louis Rivail

    Pages 561-571

17. Auxiliary Density Functional Theory: From Molecules to Nanostructures

    • Patrizia Calaminici, Victor-Daniel Domı́nguez-Soria, Roberto Flores-Moreno, Gabriel Ulises Gamboa-Martı́nez, Gerald Geudtner, Annick Goursot et al.

    Pages 573-610

18. Guide to Programs for Non-relativistic Quantum Chemistry Calculations

    • Tao Zeng, Mariusz Klobukowski

    Pages 611-630

19. Functional Nanostructures and Nanocomposites – Numerical Modeling Approach and Experiment

    • Malgorzata Makowska-Janusik, Abdel-Hadi Kassiba

    Pages 631-666

20. Structures and Stability of Fullerenes, Metallofullerenes, and Their Derivatives

    • Alexey A. Popov

    Pages 667-721

The role the Handbook of Computational Chemistry is threefold. It is primarily intended to be used as a guide that navigates the user through the plethora of computational methods currently in use; it explains their limitations and advantages; and it provides various examples of their important and varied applications.

This reference work is presented in three volumes. Volume I introduces the different methods used in computational chemistry.  Basic assumptions common to the majority of computational methods based on molecular, quantum, or statistical mechanics are outlined and special attention is paid to the limits of their applicability.

 Volume II portrays the applications of computational methods to model systems and discusses in detail molecular structures, the modelling of various properties of molecules and chemical reactions. Both ground and excited states properties are covered in the gas phase as well as in solution. This volume also describes Nanomaterials and covers topics such as clusters, periodic, and nano systems. Special emphasis is placed on the environmental effects of nanostructures.

Volume III is devoted to the important class of Biomolecules. Useful models of biological systems considered by computational chemists are provided and RNA, DNA and proteins are discussed in detail. This volume presents examples of calcualtions of their properties and interactions and reveals the role of solvents in biologically important reactions as well as the structure function relationship of various classes of Biomolecules.

• Density Functional
• Electronic Hamiltonian
• Energy Optimization
• Force field
• Molecular Dynamics
• Molecular Mechanics
• Monte Carlo Simulations
• Nanostructures
• Quantum Mechanics
• Quantum Theory

• Department of Chemistry and Biochemistry, Jackson State University, Jackson, USA

  Jerzy Leszczynski

Jerzy Leszczynski - Professor of Chemistry and President’s Distinguished Fellow at the Jackson State University (JSU) joined the faculty of the JSU Department of Chemistry in 1990. Dr. Leszczynski attended the Technical University of Wroclaw (TUW) in Wroclaw, Poland obtaining his M.S (1972) and Ph.D. (1975) degrees. During the period 1976

–1986 he served as a faculty member at the TUW. In 1986 he moved to USA, initially as a visiting scientist at the University of Florida, Quantum Theory Project (1986-88) and as a research associate at the University of Alabama at Birmingham (1988-1990). During the period 1998 – 2008 Dr. Leszczynski had served as the director for the Computational Center for Molecular Structure and Interactions (NSF-CREST Center). Since October 2008 he directs new Interdisciplinary Nanotoxicity CREST Center at JSU. Dr. Leszczynski is a computational quantum chemist whose vast areas of interest include: nature of chemical bonds, theoretical predictions of molecular potential energy surfaces and vibrational spectra, structures and properties of molecules with heavy elements, properties and structure of DNA fragments, and characteristics of nanomaterials. He also applies computational chemistry methods to environmental problems, surface chemistry and atmospheric chemistry. Two areas of his research contributions are the most noticeable: investigations of DNA fragments and development of novel techniques for investigation of properties and toxicity of nanomaterials.

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