Details

Reviews in Computational Chemistry, Volume 30


Reviews in Computational Chemistry, Volume 30


Reviews in Computational Chemistry 1. Aufl.

von: Abby L. Parrill, Kenny B. Lipkowitz

259,99 €

Verlag: Wiley
Format: EPUB
Veröffentl.: 16.03.2017
ISBN/EAN: 9781119356042
Sprache: englisch
Anzahl Seiten: 392

DRM-geschütztes eBook, Sie benötigen z.B. Adobe Digital Editions und eine Adobe ID zum Lesen.

Beschreibungen

The Reviews in Computational Chemistry series brings together leading authorities in the field to teach the newcomer and update the expert on topics centered on molecular modeling.<br /><br />•    Provides background and theory, strategies for using the methods correctly, pitfalls to avoid, applications, and references<br />•    Contains updated and comprehensive compendiums of molecular modeling software that list hundreds of programs, services, suppliers and other information that every chemist will find useful<br />•    Includes detailed indices on each volume help the reader to quickly discover particular topics<br />•    Uses a tutorial manner and non-mathematical style, allowing students and researchers to access computational methods outside their immediate area of expertise
<p>List of Contributors xi</p> <p>Foreword xiii</p> <p>Contributors to Previous Volumes xvii</p> <p><b>1 Chemical Bonding at High Pressure 1<br /></b><i>Andreas Hermann</i></p> <p>High-Pressure Science 1</p> <p>Motivation 1</p> <p>Pressure in Industrial Processes 2</p> <p>High-Pressure Experiments 2</p> <p>Pressure Effects in Materials 5</p> <p>Close Packing and Metallicity—or Not 6</p> <p>Hydrogen and Hydrogen-Rich Compounds 7</p> <p>Molecular Crystals 8</p> <p>Closed-Shell Reactivity 9</p> <p>Unusual Chemistry 9</p> <p>New Electronic States 10</p> <p>Electronic Structure Calculations on Materials Under Pressure 10</p> <p>Density and Wave Function–Based Approaches 11</p> <p>Basis Sets and Pseudopotentials 13</p> <p>Identifying High-Pressure Crystal Structures 14</p> <p>Stability of High-Pressure Phases 16</p> <p>Properties of Materials Under Pressure 20</p> <p>Mechanical Properties 21</p> <p>Electronic Properties 23</p> <p>Spectroscopic Properties 28</p> <p>Conclusions 29</p> <p>Acknowledgments 31</p> <p>References 31</p> <p><b>2 Molecular Dynamics Simulations of Shock Loading of Materials: A Review and Tutorial 43<br /></b><i>Mitchell A. Wood, Mathew J. Cherukara, Edwin Antillon, and Alejandro Strachan</i></p> <p>Introduction 43</p> <p>Shock Loading of Solids 101 44</p> <p>Chapter Organization 46</p> <p>Molecular Simulations of Shockwaves in Solids 46</p> <p>Molecular Dynamics and Coarse Grain Dynamics 46</p> <p>Direct Shock Simulations 48</p> <p>Indirect Shock Simulations: Achieving Longer Timescales 49</p> <p>Shock-Induced Plasticity and Failure 51</p> <p>Plastic Deformation 51</p> <p>Preexisting Defects: Voids and Vacancies 54</p> <p>Preexisting Defects: Polycrystalline Materials 56</p> <p>Granular Materials 56</p> <p>Dynamical Failure 57</p> <p>Critical Phenomena in Spallation and Cluster Formation 60</p> <p>Ejecta Formation and the Richtmyer–Meshkov Instability 61</p> <p>Shock-Induced Phase Transformation and Materials Synthesis 62</p> <p>Phase Transformations 63</p> <p>Shock-Induced and Shock-Assisted Chemical Reactions 69</p> <p>Reactive Composites 70</p> <p>Energetic Materials and Detonation 73</p> <p>Model Explosives: Shock to Detonation 74</p> <p>Reactive MD Simulations of Explosives 75</p> <p>Electronic Structure-Based Modeling 79</p> <p>Coarse-Grained Descriptions of Shock-Induced Chemistry 80</p> <p>Summary and Outlook 83</p> <p>Acknowledgments 84</p> <p>Appendix 84</p> <p>References 85</p> <p><b>3 Basis Sets in Quantum Chemistry 93<br /></b><i>Balazs Nagy, and Frank Jensen</i></p> <p>Introduction 93</p> <p>The Basis Set Approximation 94</p> <p>Basis Set Desiderata 96</p> <p>Types of Basis Functions 98</p> <p>Slater and Gaussian Type Functions 98</p> <p>Plane-Wave Functions 101</p> <p>Real-Space Functions 103</p> <p>Other Functions 104</p> <p>Structure and Classification of Gaussian Type Basis Sets 105</p> <p>Contracted Basis Functions 108</p> <p>Optimization of Basis Set Parameters 111</p> <p>Basis Set Augmentation 113</p> <p>Diffuse Functions 113</p> <p>Tight Functions 114</p> <p>Fitting Functions 115</p> <p>Nonatom-Centered Basis Sets 115</p> <p>Examples of Basis Sets 116</p> <p>Segmented Contracted Basis Sets 116</p> <p>General Contracted Basis Sets 117</p> <p>Property Basis Sets 119</p> <p>Electric Properties 121</p> <p>Magnetic Properties 126</p> <p>Mixed Properties 128</p> <p>Relativistic Basis Sets 129</p> <p>Pseudopotentials 130</p> <p>Basis Set Convergence 131</p> <p>Convergence of Electronic Structure Methods with Gaussian Type Basis Sets 132</p> <p>Composite Extrapolation Methods 133</p> <p>Basis Set Incompleteness and Superposition Errors 134</p> <p>Aspects of Choosing A Suitable Basis Set 136</p> <p>Availability of Basis Sets 139</p> <p>Acknowledgment 139</p> <p>References 139</p> <p><b>4 The Quantum Chemistry of Open-Shell Species 151<br /></b><i>Anna I. Krylov</i></p> <p>Introduction and Overview 151</p> <p>Quantum Chemistry Methods for Open- and Closed-Shell Species 155</p> <p>Some Aspects of Electronic Structure of Open-Shell Species 159</p> <p>Spin Contamination of Approximate Open-Shell Wave Functions 159</p> <p>Jahn–Teller Effect 160</p> <p>Vibronic Interactions and Pseudo-Jahn–Teller Effect 162</p> <p>High-Spin Open-Shell States 165</p> <p>Open-Shell States with Multiconfigurational Character 167</p> <p>EOM-IP and EOM-EA Methods for Open-Shell Systems 167</p> <p>Examples 169</p> <p>Diradicals, Triradicals, and Beyond 174</p> <p>Excited States of Open-Shell Species 181</p> <p>Metastable Radicals 186</p> <p>Bonding in Open-Shell Species 187</p> <p>Dyson Orbitals 188</p> <p>Density-Based Wave Function Analysis 189</p> <p>Insight into Bonding from Physical Observables 192</p> <p>Properties and Spectroscopy 193</p> <p>Vibrational Spectroscopy 194</p> <p>Electronic and Photoelectron Spectroscopy 194</p> <p>Electronic Transitions 200</p> <p>Outlook 207</p> <p>Acknowledgments 208</p> <p>Appendix: List of Acronyms 209</p> <p>References 210</p> <p><b>5 Machine Learning, Quantum Chemistry, and Chemical Space 225<br /></b><i>Raghunathan Ramakrishnan, and O. Anatole von Lilienfeld</i></p> <p>Introduction 225</p> <p>Paradigm 228</p> <p>Kernel Ridge Regression 230</p> <p>Representation 232</p> <p>Data 234</p> <p>Kernel 236</p> <p>Electrons 239</p> <p>Δ-Machine Learning 241</p> <p>Atoms in Molecules 245</p> <p>Crystals 247</p> <p>Conclusions and Outlook 248</p> <p>Acknowledgments 250</p> <p>References 250</p> <p><b>6 The Master Equation Approach to Problems in Chemical and Biological Physics 257<br /></b><i>Dmitrii E. Makarov</i></p> <p>Introduction 257</p> <p>The General Form of A Master Equation and its Solution 260</p> <p>Microscopic Reversibility, Detailed Balance, and Their Consequences 262</p> <p>The Kinetic Monte Carlo (KMC) Method 265</p> <p>Quantum Master Equations 270</p> <p>The Reduced Density Matrix as a Description of a Molecule Interacting with Its Surroundings 270</p> <p>Diagonal and Off-Diagonal Elements of the Density Matrix and Significance of Dephasing 273</p> <p>Relaxation 275</p> <p>Kinetic Monte Carlo for Quantum Master Equations 277</p> <p>Physical Significance of The Quantum Kinetic Monte Carlo Scheme 282</p> <p>Concluding Remarks 283</p> <p>Acknowledgments 284</p> <p>References 284</p> <p><b>7 Continuous Symmetry Measures: A New Tool in Quantum Chemistry 289<br /></b><i>Pere Alemany, David Casanova, Santiago Alvarez, Chaim Dryzun, and David Avnir</i></p> <p>Introduction 289</p> <p>Symmetry as a Fundamental Concept in Quantum Chemistry 289</p> <p>Symmetry, Pseudosymmetry, and Quasisymmetry 292</p> <p>Continuous Symmetry Measures 295</p> <p>General Definition of CSMs 295</p> <p>CSMs in Molecular Quantum Chemistry 299</p> <p>CSM for the Nuclear Framework 300</p> <p>CSMs for Matrices and Operators 303</p> <p>CSM for Functions: Electron Density, Wave Functions, and Molecular Orbitals 304</p> <p>CSMs for Irreducible Representations of a Group 307</p> <p>Pseudosymmetry Analysis of Molecular Orbitals 313</p> <p>Applications 315</p> <p>The Nature of the Chemical Bond from the Point of View of CSMs 315</p> <p>CSM Analysis of the Electronic Structure of Conjugated Hydrocarbons and Related Compounds 321</p> <p>Pseudosymmetry Analysis of the d-Block Molecular Orbitals of “Octahedral” ML6 Transition Metal Compounds 328</p> <p>Symmetry, Pseudosymmetry and Walsh Diagrams for ML4</p> <p>Compounds along the Planarization Path 334</p> <p>Conclusions 343</p> <p>Acknowledgment 344</p> <p>References 344</p> <p>Index 353</p>
<p> <b>ABBY L. PARRILL, Ph.D.,</b> is Professor of Chemistry in the Department of Chemistry at the University of Memphis, TN. Her research interests are in bioorganic chemistry, protein modeling and NMR Spectroscopy and rational ligand design and synthesis. In 2011, she was awarded the Distinguished Research Award by University of Memphis Alumni Association. She has given more than 100 presentations, and published more than 100 papers and books. <br> <br> <b>KENNY B. LIPKOWITZ, Ph.D.,</b> was one of the founding Co-editors of <i>Reviews in Computational Chemistry</i>. He spent 28 years as an academician and then moved to Office of Naval Research, a Program Manager in Computer-Aided Materials Design.
<p> This volume, similar to its previous volumes, features chapters by experts in various fields of computational chemistry. Volume 30 covers chemical bonding at high pressure, molecular dynamics simulations, basis sets in quantum chemistry, master equation approach, quantum chemistry of open-shell species, continuous symmetry measures, and machine learning. <p> <b>FROM REVIEWS OF THE SERIES</b> <p> <i>"Reviews in Computational Chemistry remains the most valuable reference to methods and techniques in computational chemistry."</i><br> Journal of Molecular Graphics And Modelling <p> <i>"One cannot generally do better than to try to find an appropriate article in the highly successful Reviews in Computational Chemistry. The basic philosophy of the editors seems to be to help the authors produce chapters that are complete, accurate, clear, and accessible to experimentalists (in particular) and other nonspecialists (in general)."</i><br> Journal of The American Chemical Society

Diese Produkte könnten Sie auch interessieren:

Hot-Melt Extrusion
Hot-Melt Extrusion
von: Dennis Douroumis
PDF ebook
136,99 €
Hot-Melt Extrusion
Hot-Melt Extrusion
von: Dennis Douroumis
EPUB ebook
136,99 €
Kunststoffe
Kunststoffe
von: Wilhelm Keim
PDF ebook
99,99 €