PRINCIPLES OF QUANTUM MECHANICS: as Applied to Chemistry and Chemical Physics DONALD D. FITTS CAMBRIDGE UNIVERSITY PRESS PRINCIPLES OF QUANTUM MECHANICS as Applied toChemistryand Chemical Physics This text presents a rigorous mathematical account of the principles of quantum mechanics, in particular as applied to chemistry and chemical physics.Applicationsareusedasillustrationsofthebasictheory. Thefirsttwochaptersserveasanintroductiontoquantumtheory,althoughit is assumed that the reader has been exposed to elementary quantum mechanics as part of an undergraduate physical chemistry or atomic physics course. Following a discussion of wave motion leading to Schro¨dinger’s wave mech- anics, the postulates of quantum mechanics are presented along with the essential mathematical concepts and techniques. The postulates are rigorously applied to the harmonic oscillator, angular momentum, the hydrogen atom, the variation method, perturbation theory, and nuclear motion. Modern theoretical concepts such as hermitian operators, Hilbert space, Dirac notation, and ladder operatorsareintroducedandusedthroughout. This advanced text is appropriate for beginning graduate students in chem- istry,chemicalphysics,molecular physics,andmaterialsscience. A native of the state of New Hampshire, Donald Fitts developed an interest in chemistry at the age of eleven. He was awarded an A.B. degree, magna cum laudewith highest honors in chemistry, in 1954from Harvard University and a Ph.D.degreeinchemistryin1957fromYaleUniversityforhistheoreticalwork with John G. Kirkwood. After one-year appointments as a National Science Foundation Postdoctoral Fellow at the Institute for Theoretical Physics, Uni- versity of Amsterdam, and as a Research Fellow at Yale’s Chemistry Depart- ment,he joinedthe facultyofthe UniversityofPennsylvania,risingtothe rank ofProfessorofChemistry. In Penn’s School of Arts and Sciences, Professor Fitts also served as Acting DeanforoneyearandasAssociateDeanandDirectoroftheGraduateDivision for fifteen years. His sabbatical leaves were spent in Britain as a NATO Senior Science Fellow at Imperial College, London, as an Academic Visitor in Physical Chemistry, University of Oxford, and as a Visiting Fellow at Corpus ChristiCollege,Cambridge. He is the author of two other books, Nonequilibrium Thermodynamics (1962) and Vector Analysis in Chemistry (1974), and has published research articles on the theory of optical rotation, statistical mechanical theory of transport processes, nonequilibrium thermodynamics, molecular quantum mechanics,theoryofliquids,intermolecularforces,andsurfacephenomena. PRINCIPLES OF QUANTUM MECHANICS as Applied to Chemistry and Chemical Physics DONALD D. FITTS UniversityofPennsylvania PUBLISHED BY CAMBRIDGE UNIVERSITY PRESS (VIRTUAL PUBLISHING) FOR AND ON BEHALF OF THE PRESS SYNDICATE OF THE UNIVERSITY OF CAMBRIDGE The Pitt Building, Trumpington Street, Cambridge CB2 IRP 40 West 20th Street, New York, NY 10011-4211, USA 477 Williamstown Road, Port Melbourne, VIC 3207, Australia http://www.cambridge.org © D. D. Fitts 1999 This edition © D. D. Fitts 2002 First published in printed format 1999 A catalogue record for the original printed book is available from the British Library and from the Library of Congress Original ISBN 0 521 65124 7 hardback Original ISBN 0 521 65841 1 paperback ISBN 0 511 00763 9 virtual (netLibrary Edition) Contents Preface viii Chapter1 Thewavefunction 1 1.1 Wavemotion 2 1.2 Wavepacket 8 1.3 Dispersionofawavepacket 15 1.4 Particlesandwaves 18 1.5 Heisenberguncertaintyprinciple 21 1.6 Young’sdouble-slitexperiment 23 1.7 Stern–Gerlachexperiment 26 1.8 Physicalinterpretationofthewavefunction 29 Problems 34 Chapter2 Schro¨dingerwavemechanics 36 2.1 TheSchro¨dingerequation 36 2.2 Thewavefunction 37 2.3 Expectationvaluesofdynamicalquantities 41 2.4 Time-independentSchro¨dingerequation 46 2.5 Particleinaone-dimensionalbox 48 2.6 Tunneling 53 2.7 Particlesinthreedimensions 57 2.8 Particleinathree-dimensionalbox 61 Problems 64 Chapter3 Generalprinciplesofquantumtheory 65 3.1 Linearoperators 65 3.2 Eigenfunctionsandeigenvalues 67 3.3 Hermitianoperators 69 v vi Contents 3.4 Eigenfunctionexpansions 75 3.5 Simultaneouseigenfunctions 77 3.6 HilbertspaceandDiracnotation 80 3.7 Postulatesofquantummechanics 85 3.8 Parityoperator 94 3.9 Hellmann–Feynmantheorem 96 3.10 Timedependenceoftheexpectationvalue 97 3.11 Heisenberguncertaintyprinciple 99 Problems 104 Chapter4 Harmonicoscillator 106 4.1 Classicaltreatment 106 4.2 Quantumtreatment 109 4.3 Eigenfunctions 114 4.4 Matrixelements 121 4.5 Heisenberguncertaintyrelation 125 4.6 Three-dimensionalharmonicoscillator 125 Problems 128 Chapter5 Angularmomentum 130 5.1 Orbitalangularmomentum 130 5.2 Generalizedangularmomentum 132 5.3 Applicationtoorbitalangularmomentum 138 5.4 Therigidrotor 148 5.5 Magneticmoment 151 Problems 155 Chapter6 Thehydrogenatom 156 6.1 Two-particleproblem 157 6.2 Thehydrogen-likeatom 160 6.3 Theradialequation 161 6.4 Atomicorbitals 175 6.5 Spectra 187 Problems 192 Chapter7 Spin 194 7.1 Electronspin 194 7.2 Spinangularmomentum 196 7.3 Spinone-half 198 7.4 Spin–orbitinteraction 201 Problems 206 Contents vii Chapter8 Systemsof identicalparticles 208 8.1 Permutationsof identicalparticles 208 8.2 Bosonsandfermions 217 8.3 Completenessrelation 218 8.4 Non-interactingparticles 220 8.5 Thefree-electrongas 226 8.6 Bose–Einsteincondensation 229 Problems 230 Chapter9 Approximationmethods 232 9.1 Variationmethod 232 9.2 Linearvariationfunctions 237 9.3 Non-degenerateperturbationtheory 239 9.4 Perturbedharmonicoscillator 246 9.5 Degenerateperturbationtheory 248 9.6 Groundstateoftheheliumatom 256 Problems 260 Chapter10 Molecularstructure 263 10.1 Nuclearstructureandmotion 263 10.2 Nuclearmotionindiatomicmolecules 269 Problems 279 AppendixA Mathematicalformulas 281 AppendixB FourierseriesandFourierintegral 285 AppendixC Diracdeltafunction 292 AppendixD Hermitepolynomials 296 AppendixE LegendreandassociatedLegendrepolynomials 301 AppendixF LaguerreandassociatedLaguerrepolynomials 310 AppendixG Seriessolutionsofdifferentialequations 318 AppendixH Recurrencerelationforhydrogen-atomexpectationvalues 329 AppendixI Matrices 331 AppendixJ Evaluationofthetwo-electroninteractionintegral 341 Selectedbibliography 344 Index 347 Physicalconstants Preface This book is intended as a text for a first-year physical-chemistry or chemical- physics graduate course in quantum mechanics. Emphasis is placed on a rigorous mathematical presentation of the principles of quantum mechanics with applications serving as illustrations of the basic theory. The material is normally covered in the first semester of a two-term sequence and is based on the graduate course that I have taught from time to time at the University of Pennsylvania. The book may also be used for independent study and as a referencethroughoutandbeyondthestudent’sacademicprogram. The first two chapters serve as an introduction to quantum theory. It is assumed that the student has already been exposed to elementary quantum mechanics and to the historical events that led to its development in an undergraduate physical chemistry course or in a course on atomic physics. Accordingly, the historical development of quantum theory is not covered. To serve as a rationale for the postulates of quantum theory, Chapter 1 discusses wavemotionandwavepacketsandthenrelatesparticlemotiontowavemotion. In Chapter 2 the time-dependent and time-independent Schro¨dinger equations are introduced along with a discussion of wave functions for particles in a potential field. Some instructors may wish to omit the first or both of these chaptersortopresentabbreviatedversions. Chapter 3 is the heart of the book. It presents the postulates of quantum mechanics and the mathematics required for understanding and applying the postulates. This chapter stands on its own and does not require the student to have read Chapters 1 and 2, although some previous knowledge of quantum mechanicsfromanundergraduatecourseishighlydesirable. Chapters 4, 5, and 6 discuss basic applications of importance to chemists. In all cases the eigenfunctions and eigenvalues are obtained by means of raising and lowering operators. There are several advantages to using this ladder operator technique over the older procedure of solving a second-order differ- viii Preface ix entialequationbytheseriessolutionmethod.Ladderoperatorsprovidepractice for the student in operations that are used in more advanced quantum theory and in advanced statistical mechanics. Moreover, they yield the eigenvalues and eigenfunctions more simply and more directly without the need to introduce generating functions and recursion relations and to consider asymp- totic behavior and convergence. Although there is no need to invoke Hermite, Legendre, and Laguerre polynomials when using ladder operators, these func- tions are nevertheless introduced in the body of the chapters and their proper- ties are discussed in the appendices. For traditionalists, the series-solution methodispresentedinanappendix. Chapters 7 and 8 discuss spin and identical particles, respectively, and each chapter introduces an additional postulate. The treatment in Chapter 7 is limited to spin one-half particles, since these are the particles of interest to chemists. Chapter 8 provides the link between quantum mechanics and statistical mechanics. To emphasize that link, the free-electron gas and Bose– Einstein condensation are discussed. Chapter 9 presents two approximation procedures, the variation method and perturbation theory, while Chapter 10 treatsmolecularstructureandnuclearmotion. The first-year graduate course in quantum mechanics is used in many chemistry graduate programs as a vehicle for teaching mathematical analysis. For this reason, this book treats mathematical topics in considerable detail, both in the main text and especially in the appendices. The appendices on Fourier series and the Fourier integral, the Dirac delta function, and matrices discuss these topics independently of their application to quantum mechanics. Moreover, the discussions of Hermite, Legendre, associated Legendre, La- guerre, and associated Laguerre polynomials in Appendices D, E, and F are more comprehensive than the minimum needed for understanding the main text.Theintentistomakethebookusefulasareferenceaswellasatext. I should like to thank Corpus Christi College, Cambridge for a Visiting Fellowship, during which part of this book was written. I also thank Simon Capelin, Jo Clegg, Miranda Fyfe, and Peter Waterhouse of the Cambridge UniversityPressfortheireffortsinproducingthisbook. DonaldD.Fitts 1 The wave function Quantum mechanics is a theory to explain and predict the behavior of particles such as electrons, protons, neutrons, atomic nuclei, atoms, and molecules, as well as the photon–the particle associated with electromagnetic radiation or light. From quantum theory we obtain the laws of chemistry as well as explanations for the properties of materials, such as crystals, semiconductors, superconductors, and superfluids. Applications of quantum behavior give us transistors, computer chips, lasers, and masers. The relatively new field of molecular biology, which leads to our better understanding of biological structures and life processes, derives from quantum considerations. Thus, quantum behavior encompasses a large fraction of modern science and tech- nology. Quantum theory was developed during the first half of the twentieth century throughtheeffortsofmanyscientists.In1926,E.Schro¨dingerinterjectedwave mechanics into the array of ideas, equations, explanations, and theories that were prevalent at the time toexplain thegrowing accumulation of observations of quantum phenomena. His theory introduced the wave function and the differential wave equation that it obeys. Schro¨dinger’s wave mechanics is now the backbone of our current conceptional understanding and our mathematical proceduresforthestudyofquantumphenomena. Our presentation of the basic principles of quantum mechanics is contained in the first three chapters. Chapter 1 begins with a treatment of plane waves and wave packets, which serves as background material for the subsequent discussion of the wave function for a free particle. Several experiments, which lead to a physical interpretation of the wave function, are also described. In Chapter 2, the Schro¨dinger differential wave equation is introduced and the wave function concept is extended to include particles in an external potential field. The formal mathematical postulates of quantum theory are presented in Chapter3. 1