| Preface to the First Edition |
| Preface to the Second Edition |
| Acknowledgments |
| What are Theory, Computation, and Modeling? / 1: |
| Definition of Terms / 1.1: |
| Quantum Mechanics / 1.2: |
| Computable Quantities / 1.3: |
| Structure / 1.3.1: |
| Potential Energy Surfaces / 1.3.2: |
| Chemical Properties / 1.3.3: |
| Cost and Efficiency / 1.4: |
| Intrinsic Value / 1.4.1: |
| Hardware and Software / 1.4.2: |
| Algorithms / 1.4.3: |
| Note on Units / 1.5: |
| Bibliography and Suggested Additional Reading |
| References |
| Molecular Mechanics / 2: |
| History and Fundamental Assumptions / 2.1: |
| Potential Energy Functional Forms / 2.2: |
| Bond Stretching / 2.2.1: |
| Valence Angle Bending / 2.2.2: |
| Torsions / 2.2.3: |
| Van der Waals Interactions / 2.2.4: |
| Electrostatic Interactions / 2.2.5: |
| Cross Terms and Additional Non-bonded Terms / 2.2.6: |
| Parameterization Strategies / 2.2.7: |
| Force-field Energies and Thermodynamics / 2.3: |
| Geometry Optimization / 2.4: |
| Optimization Algorithms / 2.4.1: |
| Optimization Aspects Specific to Force Fields / 2.4.2: |
| Menagerie of Modern Force Fields / 2.5: |
| Available Force Fields / 2.5.1: |
| Validation / 2.5.2: |
| Force Fields and Docking / 2.6: |
| Case Study: (2R*,4S*)-1-Hydroxy-2,4-dimethylhex-5-ene / 2.7: |
| Simulations of Molecular Ensembles / 3: |
| Relationship Between MM Optima and Real Systems / 3.1: |
| Phase Space and Trajectories / 3.2: |
| Properties as Ensemble Averages / 3.2.1: |
| Properties as Time Averages of Trajectories / 3.2.2: |
| Molecular Dynamics / 3.3: |
| Harmonic Oscillator Trajectories / 3.3.1: |
| Non-analytical Systems / 3.3.2: |
| Practical Issues in Propagation / 3.3.3: |
| Stochastic Dynamics / 3.3.4: |
| Monte Carlo / 3.4: |
| Manipulation of Phase-space Integrals / 3.4.1: |
| Metropolis Sampling / 3.4.2: |
| Ensemble and Dynamical Property Examples / 3.5: |
| Key Details in Formalism / 3.6: |
| Cutoffs and Boundary Conditions / 3.6.1: |
| Polarization / 3.6.2: |
| Control of System Variables / 3.6.3: |
| Simulation Convergence / 3.6.4: |
| The Multiple Minima Problem / 3.6.5: |
| Force Field Performance in Simulations / 3.7: |
| Case Study: Silica Sodalite / 3.8: |
| Foundations of Molecular Orbital Theory / 4: |
| Quantum Mechanics and the Wave Function / 4.1: |
| The Hamiltonian Operator / 4.2: |
| General Features / 4.2.1: |
| The Variational Principle / 4.2.2: |
| The Born-Oppenheimer Approximation / 4.2.3: |
| Construction of Trial Wave Functions / 4.3: |
| The LCAO Basis Set Approach / 4.3.1: |
| The Secular Equation / 4.3.2: |
| H?uckel Theory / 4.4: |
| Fundamental Principles / 4.4.1: |
| Application to the Allyl System / 4.4.2: |
| Many-electron Wave Functions / 4.5: |
| Hartree-product Wave Functions / 4.5.1: |
| The Hartree Hamiltonian / 4.5.2: |
| Electron Spin and Antisymmetry / 4.5.3: |
| Slater Determinants / 4.5.4: |
| The Hartree-Fock Self-consistent Field Method / 4.5.5: |
| Semiempirical Implementations of Molecular Orbital Theory / 5: |
| Semiempirical Philosophy / 5.1: |
| Chemically Virtuous Approximations / 5.1.1: |
| Analytic Derivatives / 5.1.2: |
| Extended Huckel Theory / 5.2: |
| CNDO Formalism / 5.3: |
| INDO Formalism / 5.4: |
| INDO and INDO/S / 5.4.1: |
| MINDO/3 and SINDO1 / 5.4.2: |
| Basic NDDO Formalism / 5.5: |
| MNDO / 5.5.1: |
| AM1 / 5.5.2: |
| PM3 / 5.5.3: |
| General Performance Overview of Basic NDDO Models / 5.6: |
| Energetics / 5.6.1: |
| Geometries / 5.6.2: |
| Charge Distributions / 5.6.3: |
| Preface to the First Edition |
| Preface to the Second Edition |
| Acknowledgments |
図書
