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Quantum chemistry and spectroscopy PDF

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Quantum Chemistry & Spectroscopy THIRD EDITION Thomas Engel University of Washington Chapter 15, “Computational Chemistry,” was contributed by Warren Hehre CEO, Wavefunction, Inc. Editor in Chief: Adam Jaworski Executive Editor: Jeanne Zalesky Senior Marketing Manager: Jonathan Cottrell Associate Editor: Jessica Neumann VP/Executive Director, Development: Carol Trueheart Development Editor: Michael Sypes Editorial Assistant: Lisa Tarabokjia Marketing Assistant: Nicola Houston Managing Editor, Chemistry and Geosciences: Gina M. Cheselka Senior Project Manager, Production: Beth Sweeten Associate Media Producer: Ashley Eklund Full Service/Compositor: GEX Publishing Services Senior Technical Art Specialist: Connie Long Illustrator: Imagineering Media Services, Inc. Design Manager: Mark Ong Interior Designer: Integra Software Services, Inc. Cover Designer: BigWig Designs Photo Manager and Researcher: Maya Melenchuk Text Permissions Manager: Beth Wollar Text Permissions Researcher: Beth Keister Operations Specialist: Jeff Sargent Cover Photo Credit: Artwork courtesy of Kim Kopp; photo credit: Frank Huster. Credits and acknowledgments borrowed from other sources and reproduced, with permission, in this textbook appear on the appropriate page within the text or on p. 489. Copyright ©2013, 2010, 2006 Pearson Education, Inc. All rights reserved. Manufactured in the United States of America. This publication is protected by Copyright, and permission should be obtained from the publisher prior to any prohibited reproduction, storage in a retrieval system, or transmission in any form or by any means, electronic, mechanical, photocopying, recording, or likewise. To obtain permission(s) to use material from this work, please submit a written request to Pearson Education, Inc., Permissions Department, 1900 E. Lake Ave., Glenview, IL 60025. For information regarding permissions, call (847) 486-2635. Many of the designations used by manufacturers and sellers to distinguish their products are claimed as trademarks. Where those designations appear in this book, and the publisher was aware of a trademark claim, the designations have been printed in initial caps or all caps. Library of Congress Cataloging-in-Publication Data Engel, Thomas Quantum chemistry and spectroscopy / Thomas Engel, Philip Reid. -- 3rd ed. p. cm. Includes index. ISBN 978-0-321-76619-9 (casebound) 1. Quantum chemistry--Textbooks. 2. Spectrum analysis--Textbooks. I. Reid, Philip (Philip J.) II. Title. QD462.E53 2012 541'.28--dc23 2011046906 1 2 3 4 5 6 7 8 9 10— CRK—15 14 13 12 11 ISBN-10:0-321-76619-9; ISBN-13:978-0-321-76619-9 www.pearsonhighered.com To Walter and Juliane, my first teachers, and to Gloria, Alex, and Gabrielle. Thomas Engel Brief Contents 1 12 From Classical to Quantum Mechanics 1 The Chemical Bond in Diatomic 2 Molecules 245 The Schrödinger Equation 17 13 3 Molecular Structure and Energy Levels for The Quantum Mechanical Postulates 39 Polyatomic Molecules 275 4 Using Quantum Mechanics on Simple 14 Electronic Spectroscopy 309 Systems 51 15 5 Computational Chemistry 339 The Particle in the Box and the Real 16 World 69 Molecular Symmetry 395 6 17 Commuting and Noncommuting Operators Nuclear Magnetic Resonance and the Surprising Consequences of Spectroscopy 423 Entanglement 91 A APPENDIX Math Supplement 455 7 A Quantum Mechanical Model for the B Vibration and Rotation of Molecules 113 APPENDIX Point Group Character Tables 477 8 The Vibrational and Rotational Spectroscopy C of Diatomic Molecules 139 APPENDIX Answers to Selected End-of-Chapter 9 Problems 485 The Hydrogen Atom 173 10 Many-Electron Atoms 191 CREDITS 489 11 Quantum States for Many-Electron Atoms and INDEX 491 Atomic Spectroscopy 215 iv Contents PREFACE x 4 Using Quantum Mechanics on Simple Systems 51 1 From Classical to Quantum 4.1 The Free Particle 51 Mechanics 1 4.2 The Particle in a One-Dimensional Box 53 4.3 Two- and Three-Dimensional Boxes 57 1.1 Why Study Quantum Mechanics? 1 4.4 Using the Postulates to Understand the Particle in 1.2 Quantum Mechanics Arose out of the Interplay of the Box and Vice Versa 58 Experiments and Theory 2 1.3 Blackbody Radiation 3 5 The Particle in the Box and the 1.4 The Photoelectric Effect 4 Real World 69 1.5 Particles Exhibit Wave-Like Behavior 6 1.6 Diffraction by a Double Slit 8 5.1 The Particle in the Finite Depth Box 69 1.7 Atomic Spectra and the Bohr Model of the 5.2 Differences in Overlap between Core and Valence Hydrogen Atom 11 Electrons 70 5.3 Pi Electrons in Conjugated Molecules Can Be 2 Treated as Moving Freely in a Box 71 The Schrödinger Equation 17 5.4 Why Does Sodium Conduct Electricity and Why 2.1 What Determines If a System Needs to Be Is Diamond an Insulator? 72 Described Using Quantum Mechanics? 17 5.5 Traveling Waves and Potential Energy Barriers 73 2.2 Classical Waves and the Nondispersive Wave 5.6 Tunneling through a Barrier 75 Equation 21 5.7 The Scanning Tunneling Microscope and the 2.3 Waves Are Conveniently Represented as Atomic Force Microscope 77 Complex Functions 25 5.8 Tunneling in Chemical Reactions 82 2.4 Quantum Mechanical Waves and the Schrödinger 5.9 (Supplemental) Quantum Wells and Equation 26 Quantum Dots 83 2.5 Solving the Schrödinger Equation: Operators, Observables, Eigenfunctions, and Eigenvalues 28 6 Commuting and Noncommuting 2.6 The Eigenfunctions of a Quantum Mechanical Operator Are Orthogonal 30 Operators and the Surprising 2.7 The Eigenfunctions of a Quantum Mechanical Consequences of Entanglement 91 Operator Form a Complete Set 32 6.1 Commutation Relations 91 2.8 Summing Up the New Concepts 34 6.2 The Stern–Gerlach Experiment 93 6.3 The Heisenberg Uncertainty Principle 96 3 The Quantum Mechanical 6.4 (Supplemental) The Heisenberg Uncertainty Postulates 39 Principle Expressed in Terms of Standard Deviations 100 3.1 The Physical Meaning Associated with the Wave Function Is Probability 40 6.5 (Supplemental) A Thought Experiment Using a Particle in a Three-Dimensional Box 102 3.2 Every Observable Has a Corresponding Operator 41 6.6 (Supplemental) Entangled States, Teleportation, and Quantum Computers 104 3.3 The Result of an Individual Measurement 42 3.4 The Expectation Value 42 3.5 The Evolution in Time of a Quantum Mechanical System 46 3.6 Do Superposition Wave Functions Really Exist? 46 v vi CONTENTS 7 10 A Quantum Mechanical Model for Many-Electron Atoms 191 the Vibration and Rotation of 10.1 Helium: The Smallest Many-Electron Atom 191 Molecules 113 10.2 Introducing Electron Spin 193 7.1 The Classical Harmonic Oscillator 113 10.3 Wave Functions Must Reflect the Indistinguishability of Electrons 194 7.2 Angular Motion and the Classical Rigid Rotor 117 10.4 Using the Variational Method to Solve the 7.3 The Quantum Mechanical Harmonic Schrödinger Equation 198 Oscillator 119 10.5 The Hartree–Fock Self-Consistent Field 7.4 Quantum Mechanical Rotation in Two Method 199 Dimensions 124 10.6 Understanding Trends in the Periodic Table 7.5 Quantum Mechanical Rotation in Three from Hartree–Fock Calculations 207 Dimensions 127 7.6 The Quantization of Angular Momentum 129 7.7 The Spherical Harmonic Functions 131 11 Quantum States for 7.8 Spatial Quantization 133 Many-Electron Atoms and Atomic Spectroscopy 215 8 The Vibrational and Rotational 11.1 Good Quantum Numbers, Terms, Levels, and Spectroscopy of Diatomic States 215 Molecules 139 11.2 The Energy of a Configuration Depends on Both Orbital and Spin Angular Momentum 217 8.1 An Introduction to Spectroscopy 139 11.3 Spin-Orbit Coupling Breaks Up a Term into 8.2 Absorption, Spontaneous Emission, and Levels 224 Stimulated Emission 141 11.4 The Essentials of Atomic Spectroscopy 225 8.3 An Introduction to Vibrational Spectroscopy 143 11.5 Analytical Techniques Based on Atomic 8.4 The Origin of Selection Rules 146 Spectroscopy 227 8.5 Infrared Absorption Spectroscopy 148 11.6 The Doppler Effect 230 8.6 Rotational Spectroscopy 151 11.7 The Helium-Neon Laser 231 8.7 (Supplemental) Fourier Transform Infrared 11.8 Laser Isotope Separation 234 Spectroscopy 157 11.9 Auger Electron and X-Ray Photoelectron 8.8 (Supplemental) Raman Spectroscopy 159 Spectroscopies 235 8.9 (Supplemental) How Does the Transition Rate 11.10 Selective Chemistry of Excited States: between States Depend on Frequency? 161 O(3P) and O(1D) 238 11.11 (Supplemental) Configurations with Paired and 9 The Hydrogen Atom 173 Unpaired Electron Spins Differ in Energy 239 9.1 Formulating the Schrödinger Equation 173 12 9.2 Solving the Schrödinger Equation for the The Chemical Bond in Diatomic Hydrogen Atom 174 Molecules 245 9.3 Eigenvalues and Eigenfunctions for the 12.1 Generating Molecular Orbitals from Atomic Total Energy 175 Orbitals 245 9.4 The Hydrogen Atom Orbitals 181 12.2 The Simplest One-Electron Molecule: 9.5 The Radial Probability Distribution + H 249 2 Function 183 + 12.3 The Energy Corresponding to the H 2 9.6 The Validity of the Shell Model of Molecular Wave Functions c and c 251 g u an Atom 187 + 12.4 A Closer Look at the H Molecular Wave 2 Functions c and c 254 g u vii CONTENTS 12.5 Homonuclear Diatomic Molecules 256 14.8 Intersystem Crossing and Phosphorescence 321 12.6 The Electronic Structure of Many-Electron 14.9 Fluorescence Spectroscopy and Analytical Molecules 260 Chemistry 322 12.7 Bond Order, Bond Energy, and Bond 14.10 Ultraviolet Photoelectron Spectroscopy 323 Length 263 14.11 Single Molecule Spectroscopy 325 12.8 Heteronuclear Diatomic Molecules 265 14.12 Fluorescent Resonance Energy 12.9 The Molecular Electrostatic Potential 268 Transfer (FRET) 327 14.13 Linear and Circular Dichroism 331 13 Molecular Structure and Energy 14.14 Assigning + and - to © Terms of Diatomic Molecules 333 Levels for Polyatomic Molecules 275 13.1 Lewis Structures and the VSEPR Model 275 15 Computational Chemistry 339 13.2 Describing Localized Bonds Using Hybridization for Methane, Ethene, and Ethyne 278 15.1 The Promise of Computational Chemistry 339 13.3 Constructing Hybrid Orbitals for Nonequivalent 15.2 Potential Energy Surfaces 340 Ligands 281 15.3 Hartree–Fock Molecular Orbital Theory: A Direct 13.4 Using Hybridization to Describe Chemical Descendant of the Schrödinger Equation 344 Bonding 284 15.4 Properties of Limiting Hartree–Fock Models 346 13.5 Predicting Molecular Structure Using 15.5 Theoretical Models and Theoretical Model Qualitative Molecular Orbital Theory 286 Chemistry 351 13.6 How Different Are Localized and Delocalized 15.6 Moving Beyond Hartree–Fock Theory 352 Bonding Models? 289 15.7 Gaussian Basis Sets 357 13.7 Molecular Structure and Energy Levels from 15.8 Selection of a Theoretical Model 360 Computational Chemistry 292 15.9 Graphical Models 374 13.8 Qualitative Molecular Orbital Theory for Conjugated and Aromatic Molecules: The 15.10 Conclusion 382 Hückel Mode 294 13.9 From Molecules to Solids 300 16 Molecular Symmetry 395 13.10 Making Semiconductors Conductive at Room Temperature 301 16.1 Symmetry Elements, Symmetry Operations, and Point Groups 395 16.2 Assigning Molecules to Point Groups 397 14 Electronic Spectroscopy 309 16.3 The H O Molecule and the C Point Group 399 2 2v 14.1 The Energy of Electronic Transitions 309 16.4 Representations of Symmetry Operators, Bases 14.2 Molecular Term Symbols 310 for Representations, and the Character Table 404 14.3 Transitions between Electronic States of 16.5 The Dimension of a Representation 406 Diatomic Molecules 313 16.6 Using the C Representations to Construct 2v Molecular Orbitals for H O 410 14.4 The Vibrational Fine Structure of Electronic 2 Transitions in Diatomic Molecules 314 16.7 The Symmetries of the Normal Modes of Vibration of Molecules 412 14.5 UV-Visible Light Absorption in Polyatomic Molecules 316 16.8 Selection Rules and Infrared versus Raman Activity 416 14.6 Transitions among the Ground and Excited States 318 16.9 (Supplemental) Using the Projection Operator Method to Generate MOs That Are Bases for 14.7 Singlet–Singlet Transitions: Absorption and Irreducible Representations 417 Fluorescence 319 viii CONTENTS 17 17.9 Peak Widths in NMR Spectroscopy 438 Nuclear Magnetic Resonance 17.10 Solid-State NMR 440 Spectroscopy 423 17.11 NMR Imaging 440 17.1 Intrinsic Nuclear Angular Momentum and 17.12 (Supplemental)The NMR Experiment in the Magnetic Moment 423 Laboratory and Rotating Frames 442 17.2 The Energy of Nuclei of Nonzero Nuclear Spin 17.13 (Supplemental) Fourier Transform NMR in a Magnetic Field 425 Spectroscopy 444 17.3 The Chemical Shift for an Isolated Atom 427 17.14 (Supplemental) Two-Dimensional NMR 448 17.4 The Chemical Shift for an Atom Embedded in a Molecule 428 A APPENDIX Math Supplement 455 17.5 Electronegativity of Neighboring Groups and B Chemical Shifts 429 APPENDIX Point Group Character Tables 477 17.6 Magnetic Fields of Neighboring Groups and C APPENDIX Answers to Selected End-of-Chapter Chemical Shifts 430 17.7 Multiplet Splitting of NMR Peaks Arises Problems 485 through Spin–Spin Coupling 431 CREDITS489 17.8 Multiplet Splitting When More Than Two Spins Interact 436 INDEX491 About the Author Thomas Engel has taught chemistry at the University of Washington for more than 20 years, where he is currently professor emeritus of chemistry. Professor Engel received his bachelor’s and master’s degrees in chemistry from the Johns Hopkins University, and his Ph.D. in chemistry from the University of Chicago. He then spent 11 years as a researcher in Germany and Switzerland, in which time he received the Dr. rer. nat. habil. degree from the Ludwig Maximilians University in Munich. In 1980, he left the IBM research laboratory in Zurich to become a faculty member at the University of Washington. Professor Engel’s research interests are in the area of surface chemistry, and he has published more than 80 articles and book chapters in this field. He has received the Surface Chemistry or Colloids Award from the American Chemical Society and a Senior Humboldt Research Award from the Alexander von Humboldt Foundation. ix

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