Canonical Approaches to Interatomic Interactions: Theory and Applications
Autor Luis A. Rivera-Rivera, Jay R. Waltonen Limba Engleză Paperback – 21 oct 2025
Beginning with an introduction to Potential Energy Surfaces (PES) and modern approaches in Part 1, Part 2 goes on to describe Canonical Approaches in detail, including methodologies and data to allow replication. Part 3 then goes on to outline some key applications, before future directions are discussed in Part 4.
Sharing the insight of its progressive authors, Canonical Approaches to Interatomic Interactions: Theory and Applications is an informative guide for all those working with interatomic interactions and PES, including researchers in in chemical kinetics and bonding, molecular mechanics, quantum chemistry and molecular modelling.
- Outlines both traditional and novel theories and models for intermolecular interactions
- Reviews modern interpolation and fitting methods, and highlights advantages and disadvantages for each
- Provides data and methodologies for novel canonical approaches to generating potential energy surfaces, encouraging replication
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Specificații
ISBN-13: 9780323911559
ISBN-10: 0323911552
Pagini: 266
Dimensiuni: 152 x 229 x 14 mm
Greutate: 0.41 kg
Editura: ELSEVIER SCIENCE
ISBN-10: 0323911552
Pagini: 266
Dimensiuni: 152 x 229 x 14 mm
Greutate: 0.41 kg
Editura: ELSEVIER SCIENCE
Cuprins
Part 1: Introduction to Potential Energy Surfaces
Chapter 1: The Born−Oppenheimer Approximation
1.1: Definitions of key terms
1.2: Underpinning knowledge (‘foundational’)
Chapter 2: Potential Energy Surfaces and Its Implications to Chemistry
2.1: Molecular Structure
2.2: Molecular Spectroscopy
2.3: Reaction Dynamics
Chapter 3: Review of Modern Interpolations and Fitting Methods to Generate Potential Energy Surfaces.
3.1: Definitions of key terms
3.2: Underpinning knowledge (‘foundational’)
3.3: Detailed methods/protocols
3.4: Step-by-step guidance on key procedures/processes
Chapter 4: The Hellmann−Feynman and the Virial Theorems
4.1: Definitions of key terms
4.2: Underpinning knowledge (‘foundational’)
Part 2: Canonical Approaches
Chapter 5: Canonical Approaches to Pairwise Interatomic Interactions
5.1: Introduction
5.2: Methods
5.2.1: Pointwise Force Method
5.2.2: Average Force Method
5.2.3: Structured vs Unstructured Methods
5.3: Case studies
5.3.1 Preliminaries
5.3.2 Case Studies
5.4: Computational Cost and Efficiency
5.4.1: Approximation Accuracy
5.4.2 Approximation Computational Cost
5.4.3 Case Studies of Canonical Approximation Accuracy Versus Computational Cost
5.5: Conclusions
Chapter 6: Canonical Approaches to Forces in Molecules
6.1: Introduction
6.2: Methods
6.2.1 Computational Cost of Force Evaluations
6.2.2 Piecewise Canonical Approximation Error
6.3: Feynman Force Qualitative Properties
6.4: Case studies and Results
6.5: Conclusions
Chapter 7: Canonical Approaches and the Unification of Pairwise Interatomic Interactions
7.1: Introduction
7.2: Case studies and Results
7.3: Discussion and Conclusion
Part 3: Applications and Case Studies
Chapter 8: Canonical Approaches and the Born−Oppenheimer Approximation
8.1: Introduction
8.2: Methods
8.3: Case studies and Results
8.4: Discussion & Conclusions
Chapter 9: Canonical Approaches and the Virial Theorem
9.1: Introduction
9.2: Methods
9.3: Case studies and Results
9.4: Discussion & Conclusions
Chapter 10: Canonical Approaches to Multidimensional Potential Energy Surfaces
10.1: Introduction
10.2: Methods
10.3: Case studies
10.4: Discussion & Conclusion
Chapter 1: The Born−Oppenheimer Approximation
1.1: Definitions of key terms
1.2: Underpinning knowledge (‘foundational’)
Chapter 2: Potential Energy Surfaces and Its Implications to Chemistry
2.1: Molecular Structure
2.2: Molecular Spectroscopy
2.3: Reaction Dynamics
Chapter 3: Review of Modern Interpolations and Fitting Methods to Generate Potential Energy Surfaces.
3.1: Definitions of key terms
3.2: Underpinning knowledge (‘foundational’)
3.3: Detailed methods/protocols
3.4: Step-by-step guidance on key procedures/processes
Chapter 4: The Hellmann−Feynman and the Virial Theorems
4.1: Definitions of key terms
4.2: Underpinning knowledge (‘foundational’)
Part 2: Canonical Approaches
Chapter 5: Canonical Approaches to Pairwise Interatomic Interactions
5.1: Introduction
5.2: Methods
5.2.1: Pointwise Force Method
5.2.2: Average Force Method
5.2.3: Structured vs Unstructured Methods
5.3: Case studies
5.3.1 Preliminaries
5.3.2 Case Studies
5.4: Computational Cost and Efficiency
5.4.1: Approximation Accuracy
5.4.2 Approximation Computational Cost
5.4.3 Case Studies of Canonical Approximation Accuracy Versus Computational Cost
5.5: Conclusions
Chapter 6: Canonical Approaches to Forces in Molecules
6.1: Introduction
6.2: Methods
6.2.1 Computational Cost of Force Evaluations
6.2.2 Piecewise Canonical Approximation Error
6.3: Feynman Force Qualitative Properties
6.4: Case studies and Results
6.5: Conclusions
Chapter 7: Canonical Approaches and the Unification of Pairwise Interatomic Interactions
7.1: Introduction
7.2: Case studies and Results
7.3: Discussion and Conclusion
Part 3: Applications and Case Studies
Chapter 8: Canonical Approaches and the Born−Oppenheimer Approximation
8.1: Introduction
8.2: Methods
8.3: Case studies and Results
8.4: Discussion & Conclusions
Chapter 9: Canonical Approaches and the Virial Theorem
9.1: Introduction
9.2: Methods
9.3: Case studies and Results
9.4: Discussion & Conclusions
Chapter 10: Canonical Approaches to Multidimensional Potential Energy Surfaces
10.1: Introduction
10.2: Methods
10.3: Case studies
10.4: Discussion & Conclusion