Molecular Symmetry

Symmetry and group theory provide us with a rigorous method for the description of the geometry of objects by describing the patterns in their structure. In chemistry it is a powerful concept that underlies many apparently disparate phenomena. Symmetry allows us to accurately describe the types of bonding that can occur between atoms or groups of atoms in molecules. It also governs the transitions that may occur between energy levels in molecular systems, leading to a predictive understanding of the absorption properties of molecules and hence their spectra. 
Molecular Symmetry lays out the formal language used in the area, with illustrative examples of particular molecules throughout. It then applies the ideas of symmetry and group theory to describe molecular structure, bonding in molecules and to consider the implications in spectroscopy. Topics covered include:
Symmetry  elementsSymmetry operations and products of operationsPoint groups used with moleculesPoint group representations, matrices and basis setsReducible and irreducible representationsApplications in vibrational spectroscopyMolecular orbital theory of chemical bonding       
Molecular Symmetry is designed to introduce the subject by combining symmetry with spectroscopy and bonding in a clear and accessible manner. Each chapter ends with a summary of learning points, a selection of self–test questions, and suggestions for further reading. A set of appendices includes templates for paper models which will help students understand symmetry operations and cover key aspects of the material in depth.
Molecular Symmetry is a must–have introduction to this fundamental topic for students of chemistry, and will also find a place on the bookshelves of postgraduates and researchers looking for a broad and modern introduction to the subject.

Spis treści:
Preface.
1. Symmetry Elements and Operations.
1.1 Introduction.
1.2 Symmetry Elements and Operations.
1.3 Examples of the Impact of Geometric Symmetry on Chemistry.
1.4 Summary.
1.5 Self–Test Questions.
Further Reading.
2. More Symmetry Operations and Products of Operations.
2.1 Introduction.
2.2 Background to Point Groups.
2.3 Closed Groups and New Operations.
2.4 Properties of Symmetry Operations.
2.5 Chirality and Symmetry.
2.6 Summary.
2.7 Completed Multiplication Tables.
2.8 Self–Test Questions.
3. The Point Groups Used with Molecules.
3.1 Introduction.
3.2 Molecular Classification Using Symmetry Operations.
3.3 Constructing Reference Models with Idealized Symmetry.
3.4 The Nonaxial Groups: Cs,Ci,C1.
3.5 The Cyclic Groups: Cn, Sn.
3.6 Axial Groups Containing Mirror Planes: Cnh and Cnv.
3.6.1 Examples of Axial Groups Containing Mirror Planes: Cnh and Cnv.
3.7 Axial Groups with Multiple Rotation Axes: Dn, Dnd and Dnh.
3.8 Special Groups for Linear Molecules: Cìv and Dìh.
3.9 The Cubic Groups: Td and Oh.
3.10 Assigning Point Groups to Molecules.
3.11 Example Point Group Assignments.
3.12 Self–Test Questions.
4. Point Group Representations, Matrices and Basis Sets.
4.1 Introduction.
4.2 Symmetry Representations and Characters.
4.3 Multiplication Tables for Character Representations.
4.4 Matrices and Symmetry Operations.
4.5 Diagonal and Off–Diagonal Matrix Elements.
4.6 The Trace of a Matrix as the Character for an Operation.
4.7 Noninteger Characters.
4.8 Reducible Representations.
4.9 Classes of Operations.
4.10 Degenerate Irreducible Representations.
4.11 The Labelling of Irreducible Representations.
4.12 Summary.
4.13 Completed Tables.
4.14 Self–Test Questions.
Further Reading.
5. Reducible and Irreducible Representations.
5.1 Introduction.
5.2 Irreduci ble Representations and Molecular Vibrations.
5.3 Finding Reducible Representations.
5.4 Properties of Point Groups and Irreducible Representations.
5.5 The Reduction Formula.
5.6 A Complete Set of Vibrational Modes for H2O.
5.7 Choosing the Basis Set.
5.8 The d–Orbitals in Common Transition Metal Complex Geometries.
5.9 Linear Molecules: Groups of Infinite Order.
5.10 Summary.
5.11 Self–Test Questions.
6. Applications in Vibrational Spectroscopy.
6.1 Introduction.
6.2 Selection Rules.
6.3 General Approach to Analysing Vibrational Spectroscopy.
6.4 Symmetry–Adapted Linear Combinations.
6.5 Normalization.
6.6 The Projector Operator Method.
6.7 Linking Results for Symmetry–Inequivalent Sets of Atoms.
6.8 Additional Examples.
6.9 Summary.
6.10 Self–Test Questions.
Further Reading.
7. Symmetry in Chemical Bonding.
7.1 Introduction.
7.2 Bond Energies.
7.3 The Relative Energies of Hydrogen–Like Atomic Orbitals.
7.4 The Molecules Formed by Other Second–Row Elements with Hydrogen.
7.5 The Second–Row Diatomic Molecules.
7.6 More Complex Polyatomic Molecules.
7.7 Metal Complexes.
7.8 Summary.
7.9 Self–Test Questions.
Further Reading.
Appendices.
Appendix 1. H2O Models for Identifying the Results of Symmetry Operation Products.
Appendix 2. Assignment of Chiral Centre Handedness using Cahn–Ingold–Prelog Rules.
Appendix 3. Model of a Tetrahedron and the Related Cube.
Appendix 4. Model of an Octahedron.
Appendix 5. Matrices and Determinants.
Appendix 6. The Mathematical Background to Infrared Selection Rules.
Appendix 7. The Franck–Condon Principle.
Appendix 8. Classical Treatment of Stokes/Anti–Stokes Absorption.
Appendix 9. The Atomic Orbitals of Hydrogen.
Appendix 10. The Origin of Chemical Bonding in H+2.
Appendix 11. H2O Molecular Orbital Calculation in C2v Symmetry.
Appendix 12. Character Tables.
Index.