P. W. Atkins and R. S. Friedman. Molecular Quantum Mechanics THIRD EDITION

Similar documents
FYS-6306 QUANTUM THEORY OF MOLECULES AND NANOSTRUCTURES

MOLECULAR SPECTROSCOPY

Chemistry 483 Lecture Topics Fall 2009

QUANTUM MECHANICS. Franz Schwabl. Translated by Ronald Kates. ff Springer

QUANTUM MECHANICS SECOND EDITION G. ARULDHAS

Spectra of Atoms and Molecules. Peter F. Bernath

Chemistry 881 Lecture Topics Fall 2001

Quantum Mechanics: Fundamentals

CONTENTS. vii. CHAPTER 2 Operators 15

Fundamentals of Spectroscopy for Optical Remote Sensing. Course Outline 2009

Practical Quantum Mechanics

Physics of atoms and molecules

Quantum Mechanics: Foundations and Applications

Chemistry 3502/4502. Final Exam Part I. May 14, 2005

Chemistry 218 Spring Molecular Structure

LECTURES ON QUANTUM MECHANICS

Quantum Physics II (8.05) Fall 2002 Outline

Lectures on Quantum Mechanics

Chem 442 Review of Spectroscopy

Students are required to pass a minimum of 15 AU of PAP courses including the following courses:

Wolfgang Demtroder. Molecular Physics. Theoretical Principles and Experimental Methods WILEY- VCH. WILEY-VCH Verlag GmbH & Co.

COPYRIGHTED MATERIAL. Index

Chemistry 3502/4502. Final Exam Part I. May 14, 2005

Modern Optical Spectroscopy

Quantum Physics in the Nanoworld

The Raman Effect. A Unified Treatment of the Theory of Raman Scattering by Molecules. DerekA. Long

Paradigms in Physics: Quantum Mechanics

NPTEL/IITM. Molecular Spectroscopy Lectures 1 & 2. Prof.K. Mangala Sunder Page 1 of 15. Topics. Part I : Introductory concepts Topics

Atoms and Molecules Interacting with Light Atomic Physics for the Laser Era

INTRODUCTION TO THE STRUCTURE OF MATTER

Introduction to Modern Physics

ATOMIC AND LASER SPECTROSCOPY

PHYSICS. Course Syllabus. Section 1: Mathematical Physics. Subject Code: PH. Course Structure. Electromagnetic Theory

Lecture Notes. Quantum Theory. Prof. Maximilian Kreuzer. Institute for Theoretical Physics Vienna University of Technology. covering the contents of

Symmetries in Quantum Physics

Time part of the equation can be separated by substituting independent equation

Topics for the Qualifying Examination

List of Comprehensive Exams Topics

PRINCIPLES OF NONLINEAR OPTICAL SPECTROSCOPY

MODERN PHYSICS Frank J. Blatt Professor of Physics, University of Vermont

Theory and Experiment

( ) x10 8 m. The energy in a mole of 400 nm photons is calculated by: ' & sec( ) ( & % ) 6.022x10 23 photons' E = h! = hc & 6.

MOLECULAR LIGHT SCATTERING AND OPTICAL ACTIVITY

Preface Introduction to the electron liquid

Solid State Physics. GIUSEPPE GROSSO Professor of Solid State Physics, Department of Physics, University of Pavia, and INFM

Group Theory and Its Applications in Physics

A. F. J. Levi 1 EE539: Engineering Quantum Mechanics. Fall 2017.

(8) Atomic Physics (1½l, 1½p)

What dictates the rate of radiative or nonradiative excited state decay?

DEPARTMENT OF PHYSICS UNIVERSITY OF PUNE PUNE SYLLABUS for the M.Phil. (Physics ) Course

CLASSICAL ELECTRICITY

CHAPTER 13 Molecular Spectroscopy 2: Electronic Transitions

The Basics of Theoretical and Computational Chemistry

Quantum. Mechanics. Y y. A Modern Development. 2nd Edition. Leslie E Ballentine. World Scientific. Simon Fraser University, Canada TAIPEI BEIJING

Shigeji Fujita and Salvador V Godoy. Mathematical Physics WILEY- VCH. WILEY-VCH Verlag GmbH & Co. KGaA

Study Plan for Ph.D in Physics (2011/2012)

Chiroptical Spectroscopy

PAPER No. : 8 (PHYSICAL SPECTROSCOPY) MODULE No. : 5 (TRANSITION PROBABILITIES AND TRANSITION DIPOLE MOMENT. OVERVIEW OF SELECTION RULES)

Magnetism in Condensed Matter

NERS 311 Current Old notes notes Chapter Chapter 1: Introduction to the course 1 - Chapter 1.1: About the course 2 - Chapter 1.

Molecular orbitals, potential energy surfaces and symmetry

wbt Λ = 0, 1, 2, 3, Eq. (7.63)

Department of Physics

Chem 442 Review for Exam 2. Exact separation of the Hamiltonian of a hydrogenic atom into center-of-mass (3D) and relative (3D) components.

Chemistry Physical Chemistry II Spring 2019

Lectures on Quantum Gases. Chapter 5. Feshbach resonances. Jook Walraven. Van der Waals Zeeman Institute University of Amsterdam

Chemistry Physical Chemistry II Spring 2018

Chemistry Physical Chemistry II Spring 2017

PHYSICAL CHEMISTRY. Donald A. McQuarrie UNIVERS1TY OF CALIFORNIA, DAVIS. John D. Simon UNIVERSITY OF CALIFORNIA, SAN DIEGO

QUANTUM MECHANICS. Yehuda B. Band. and Yshai Avishai WITH APPLICATIONS TO NANOTECHNOLOGY AND INFORMATION SCIENCE

AS GRS 713 Astronomical Spectroscopy

LECTURE NOTES. Ay/Ge 132 ATOMIC AND MOLECULAR PROCESSES IN ASTRONOMY AND PLANETARY SCIENCE. Geoffrey A. Blake. Fall term 2016 Caltech

Spin Dynamics Basics of Nuclear Magnetic Resonance. Malcolm H. Levitt

St Hugh s 2 nd Year: Quantum Mechanics II. Reading. Topics. The following sources are recommended for this tutorial:

Lecture 4 Quantum mechanics in more than one-dimension

Modern Physics for Scientists and Engineers International Edition, 4th Edition

Chem 467 Supplement to Lecture 19 Hydrogen Atom, Atomic Orbitals

Lecture 9 Electronic Spectroscopy

Introductory Physical Chemistry Final Exam Points of Focus

Chapter IV: Electronic Spectroscopy of diatomic molecules

Quantum Mechanics for Scientists and Engineers

Nuclear Physics for Applications

The general solution of Schrödinger equation in three dimensions (if V does not depend on time) are solutions of time-independent Schrödinger equation

METHODS OF THEORETICAL PHYSICS

Physics 221A Fall 1996 Notes 19 The Stark Effect in Hydrogen and Alkali Atoms

M.Sc. Physics

Quantum mechanics (QM) deals with systems on atomic scale level, whose behaviours cannot be described by classical mechanics.

3: Many electrons. Orbital symmetries. l =2 1. m l

Electronic Spectra of Complexes

Laser Physics OXFORD UNIVERSITY PRESS SIMON HOOKER COLIN WEBB. and. Department of Physics, University of Oxford

5.80 Small-Molecule Spectroscopy and Dynamics

Lecture 10. Transition probabilities and photoelectric cross sections

SOLID STATE PHYSICS. Second Edition. John Wiley & Sons. J. R. Hook H. E. Hall. Department of Physics, University of Manchester

Atomic Physics 3 rd year B1

The Oxford Solid State Basics

The Transition to Chaos

Last Name or Student ID

Molecular Aggregation

Relativistic corrections of energy terms

Multielectron Atoms.

Transcription:

P. W. Atkins and R. S. Friedman Molecular Quantum Mechanics THIRD EDITION Oxford New York Tokyo OXFORD UNIVERSITY PRESS 1997

Introduction and orientation 1 Black-body radiation 1 Heat capacities 2 The photoelectric and Compton effects 3 Atomic spectra 4 The duality of matter 6 Problems 7 Further reading 8 1 The foundations of quantum mechanics 9 Operators in quantum mechanics 9 1.1 Eigenfunctions and eigenvalues 9 1.2 Representations 11 1.3 Commutation and non-commutation 11 1.4 The construction of Operators 12 1.5 Linear Operators 14 1.6 Integrals over Operators 14 The postulates of quantum mechanics 15 1.7 States and wavefunctions 15 1.8 The fundamental prescription 16 1.9 The outcome of measurements 16 1.10 The interpretation of the wavefunction 18 1.11 The equation for the wavefunction 18 1.12 The Separation of the Schrödinger equation 19 Hermitian Operators 21 1.13 Definitions 21 1.14 Dirac bracket notation 22 1.15 The properties of hermitian Operators 23 The specification of states: complementarity 24 The uncertainty principle 25 1.16 Formal derivation of the principle 25 1.17 Consequences of the uncertainty principle 27 1.18 The uncertainty in energy and time 28 Time-evolution and conservation laws 29 Matrices in quantum mechanics 30 1.19 Matrix elements 31 1.20 The diagonalization of the hamiltonian 32

viii Contents The plausibility of the Schrödinger equation 34 1.21 The propagation oflight 34 1.22 The propagation ofparticles 37 1.23 The transition to quantum mechanics 37 Problems 39 Further reading 41 2 Linear motion and the harmonic osciuator 42 The characteristics of acceptable wavefunctions 42 Some general remarks on the Schrödinger equation 43 2.1 The curvature of the wavefunction 43 2.2 Qualitative Solutions 44 2.3 The emergence of quantization 44 2.4 Penetration into nonclassical regions 45 Translational motion 46 2.5 Energy and momentum 46 2.6 The significance of the coefncients 47 2.7 The flux density 48 2.8 Wavepackets 49 Penetration into and through barriers 50 2.9 An infinitely thick potential wall 50 2.10 A barrier of finite width 51 2.11 The Eckart potential barrier 54 Particle in a box 54 2.12 The Solutions 54 2.13 Features of the Solutions 56 2.14 The two-dimensional Square well 56 2.15 Degeneracy 58 The harmonic osciuator 59 2.16 The Solutions 61 2.17 Properties of the Solutions 62 2.18 The classical limit 64 Translation revisited: the scattering matrix 65 Problems 67 Further reading 70 3 Rotational motion and the hydrogen atom 71 Particle on a ring 71

IX 3.1 The hamiltonian and the Schrödinger equation 71 3.2 The angular momentum 73 3.3 The shapes of the wavefunctions 74 3.4 The classical limit 76 Particle on a sphere 76 3.5 The Schrödinger equation and its Solution 76 3.6 The angular momentum of the particle 79 3.7 Properties of the Solutions 81 3.8 The rigid rotor 81 Motion in a Coulombic field 84 3.9 The Schrödinger equation for hydrogenic atoms 84 3.10 The Separation of the relative coordinates 84 3.11 The radial Schrödinger equation 85 3.12 Probabilities and the radial distribution function 89 3.13 Atomic orbitals 90 3.14 The degeneracy of hydrogenic atoms 94 Problems 95 Further reading 97 4 Angular momentum 98 The angular momentum Operators 98 4.1 The Operators and their commutation relations 98 4.2 Angular momentum observables 100 4.3 The shift Operators 101 The definition of the states 102 4.4 The effect of the shift Operators 102 4.5 The eigenvalues of the angular momentum 103 4.6 The matrix elements of the angular momentum 103 4.7 The angular momentum eigenfunctions 107 4.8 Spin 109 The angular momenta of composite Systems 110 4.9 The specification of coupled states 110 4.10 The permitted values of the total angular momentum 111 4.11 The vector model of coupled angular momenta 113 4.12 The relation between schemes 115 4.13 The coupling of several angular momenta 119 Problems 119 Further reading 121

5 Group theory 122 The symmetries of objects, 122 5.1 Symmetry Operations and elements 122 5.2 The Classification of molecules 124 The calculus of symmetry 125 5.3 The definition of a group 126 5.4 Group multiplication tables 127 5.5 Matrix representations 128 5.6 The properties of matrix representations 132 5.7 The characters of representations 135 5.8 Characters and classes 136 5.9 Irreducible representations 137 5.10 The great and little orthogonality theorems 139 Reduced representations 143 5.11 The reduction of representations 143 5.12 Symmetry-adapted bases 145 The symmetry properties of functions 148 5.13 The transformation ofp-orbitals 148 5.14 The decomposition of direct-product bases 149 5.15 Direct-product groups 152 5.16 Vanishing integrals 154 5.17 Symmetry and degeneracy 156 The füll rotation group 157 5.18 The generators of rotations 157 5.19 The representation of the füll rotation group 159 5.20 Coupled angular momenta 161 Applications 161 Problems 162 Further reading 163 6 Techniques of approximation 164 Time-independent perturbation theory 164 6.1 Perturbation of a two-level system 164 6.2 Many-level Systems 166 6.3 The first-order correction to the energy 168 6.4 The first-order correction to the wavefunction 169 6.5 The second-order correction to the energy 170 6.6 Comments on the perturbation expressions 171 6.7 The closure approximation 173 6.8 Perturbation theory for degenerate states 175

xi Variation theory 178 6.9 The Rayleigh ratio 178 6.10 The Rayleigh-Ritz method 180 The Hellmann-Feynman theorem 182 Time-dependent perturbation theory 184 6.11 The time-dependent behaviour of a two-level system 184 6.12 The Rabi formula 187 6.13 Many-level Systems: the Variation of constants 188 6.14 The effect of a slowly switched constant perturbation 190 6.15 The effect of an oscillating perturbation 192 6.16 Transition rates to continuum states 193 6.17 The Einstein transition probabilities 195 6.18 Lifetime and energy uncertainty 198 Problems 199 Further reading 201 7 Atomic spectra and atomic structure 202 The spectrum of atomic hydrogen 202 7.1 The energies of the transitions 202 7.2 Selection rules 203 7.3 Orbital and spin magnetic moments 206 7.4 Spin-orbit coupling 208 7.5 The fine-structure of spectra 209 7.6 Term symbols and spectral details 210 7.7 The detailed spectrum of hydrogen 211 The structure of helium 212 7.8 The helium atom 212 7.9 Excited states of helium 215 7.10 The spectrum of helium 217 7.11 The Pauli principle 218 Many-electron atoms 221 7.12 Penetration and shielding 221 7.13 Periodicity 223 7.14 Slater atomic orbitals 225 7.15 Self-consistent fields 225 7.16 Term symbols and transitions of many-electron atoms 228 7.17 Hund's rules and the relative energies of terms 231 7.18 Alternative coupling schemes 232 Atoms in external fields 233 7.19 The normal Zeeman effect 7.20 The anomalous Zeeman effect 233 234

J 7.21 The Stark effect 236 Problems 237 Further reading 239 8 An introduction to molecular structure 240 The Born-Oppenheimer approximation 240 8.1 The formulation of the approximation 241 8.2 An application: the hydrogen molecule-ion 242 Molecular orbital theory 244 8.3 Linear combinations of atomic orbitals 244 8.4 The hydrogen molecule 248 8.5 Configuration interaction 250 8.6 Diatomic molecules 251 8.7 Heteronuclear diatomic molecules 254 Molecular orbital theory of polyatomic molecules 255 8.8 Symmetry-adapted linear combinations 255 8.9 Conjugated rc-systems 258 8.10 Ligandfield theory 262 8.11 Further aspects of ligand field theory 265 The band theory of solids 266 8.12 The tight-binding approximation 267 8.13 The Kronig-Penney model 269 8.14 Brillouin zones 271 Problems 273 Further reading 275 9 The calculation of electronic structure 276 The Hartree-Fock self-consistent field method 277 9.1 The formulation of the approach 277 9.2 The Hartree-Fock approach 278 9.3 Restricted and unrestricted Hartree-Fock calculations 279 9.4 The Roothaan equations 281 9.5 The selection of basis sets 285 9.6 Calculational accuracy and the basis set 290 Electron correlation 291 9.7 Configuration State functions 291 9.8 Configuration interaction 292 9.9 CI calculations 293 9.10 Multiconfiguration and multireference methods 297

XIII 9.11 Moller-Plesset many-body perturbation theory 298 Density functional theory 301 Gradient methods and molecular properties 304 Semiempirical methods 307 9.12 Conjugated rc-electron Systems 308 9.13 Neglect of differential overlap 311 Software packages for electronic structure calculations 314 Problems 316 Further reading 318 10 Molecular rotations and vibrations 320 Spectroscopic transitions 320 10.1 Absorption and emission 320 10.2 Raman processes 322 Molecular rotation 322 10.3 Rotational energy levels 323 10.4 Centrifugal distortion 326 10.5 Pure rotational selection rules 328 10.6 Rotational Raman selection rules 330 10.7 Nuclear statistics 331 Molecular Vibration 335 10.8 The vibrational energy levels of diatomic molecules 335 10.9 Anharmonic oscillation 337 10.10 Vibrational selection rules 338 10.11 Vibration-rotation spectra of diatomic molecules 340 10.12 Vibrational Raman transitions of diatomic molecules 341 The vibrations of polyatomic molecules 342 10.13 Normal modes 343 10.14 Vibrational selection rules for polyatomic molecules 346 10.15 Group theory and molecular vibrations 347 10.16 The effects of anharmonicity 351 10.17 Coriolis forces 353 10.18 Inversion doubling 354 Problems 355 Further reading 357 11 Molecular electronic transitions 358 The states of diatomic molecules 358

11.1 The Hund coupling cases 358 11.2 Decoupling and /t-doubling 360 11.3 Selection rules 361 Vibronic transitions 362 11.4 The Franck-Condon principle 362 11.5 The structure of vibronic transitions 364 The electronic spectra of polyatomic molecules 365 11.6 Symmetry considerations 365 11.7 Chromophores 366 11.8 Vibronically allowed transitions 367 11.9 Singlet-triplet transitions 370 The fates of excited species 371 11.10 Non-radiative decay 371 11.11 Radiative decay 372 11.12 The conservation of orbital symmetry 374 11.13 Electrocyclic reactions 374 11.14 Cycloaddition reactions 376 11.15 Photochemically induced electrocyclic reactions 377 11.16 Photochemically induced cycloaddition reactions 379 Problems 380 Further reading 381 12 The electric properties of molecules 382 The response to electric fields 382 12.1 Molecular response parameters 382 12.2 The static electric polarizability 384 12.3 Polarizability and molecular properties 386 12.4 Polarizabilities and molecular spectroscopy 388 12.5 Polarizabilities and dispersion forces 389 12.6 Retardation effects 392 Bulk electrical properties 393 12.7 The relative permittivity and the electric susceptibility 393 12.8 Polar molecules 395 12.9 Refractive index 397 Optical activity 401 12.10 Circular birefringence and optical rotation 402 12.11 Magnetically induced polarization 404 12.12 Rotational strength 405 Problems 409 Further reading 410

xv 13 The magnetic properties of molecules 411 The description of magnetic fields 411 13.1 The magnetic susceptibility 411 13.2 Paramagnetism 412 13.3 Vector functions 414 13.4 Derivatives of vector functions 415 13.5 The vector potential 416 Magnetic perturbations 417 13.6 The perturbation hamiltonian 418 13.7 The magnetic susceptibility 419 13.8 The current density 422 13.9 The diamagnetic current density 425 13.10 The paramagnetic current density 426 Magnetic resonance parameters 427 13.11 Shielding constants ' 427 13.12 The diamagnetic contribution to shielding 431 13.13 The paramagnetic contribution to shielding 433 13.14 The g-value 434 13.15 Spin-spin coupling 437 13.16 Hyperfine interactions 438 13.17 Nuclear spin-spin coupling 442 Problems 445 Further reading 447 14 Scattering theory 448 The formulation of scattering events 448 14.1 The scattering cross-section 448 14.2 Stationary scattering states 449 14.3 The integral scattering equation 453 14.4 The Born approximation 455 Partial-wave stationary scattering states 457 14.5 Partial waves 457 14.6 The partial-wave equation 458 14.7 Free-particle radial wavefunctions 459 14.8 The scattering phase shift 460 14.9 Phase shifts and scattering cross-sections 462 14.10 Scattering by a spherical Square well 464 14.11 Backgrounds and resonances 466 14.12 The Breit-Wigner formula 468 14.13 The scattering matrix element 470

xvi Contents Multichannel scattering 472 14.14 Channels for scattering 472 14.15 Multichannel stationary scattering states 474 14.16 Inelastic collisions 474 14.17 Reactive scattering 478 14.18 The S matrix and multichannel resonances 479 Problems 480 Further reading 483 Further Information 484 Classical mechanics 484 1 Action 484 2 The canonical momentum 486 3 The virial theorem 487 4 Reduced mass 488 Solutions of the Schrödinger equation 490 5 The motion of wavepackets 490 6 The harmonic oscillator: Solution by factorization 492 7 The harmonic oscillator: the Standard Solution 494 8 The radial wave equation 496 9 The angular wavefunction 497 10 Molecular integrals 498 11 The Hartree-Fock equations 499 12 Green's functions 502 13 The unitarity of the S matrix 504 Group theory and angular momentum 505 14 The orthogonality of basis functions 505 15 Vector coupling coefficients 506 Spectroscopic properties 507 16 Electric dipole transitions 507 17 Oscillator strength 509 18 Sum rules 510 19 Normal modes: an example 512 The electromagnetic field 514 20 The Maxwell equations 514 21 The dipolar vector potential 516 Mathematical relations 518 22 Vector properties 518 23 Matrices 519

xvii Appendix 523 1 Character tables and direct products 523 2 Vector coupling coefficients 527 Answers to selected problems 528 Index 533

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback