ebook img

Hartree-Fock Ab Initio Treatment of Crystalline Systems PDF

201 Pages·1988·11.01 MB·English
Save to my drive
Quick download
Download
Most books are stored in the elastic cloud where traffic is expensive. For this reason, we have a limit on daily download.

Preview Hartree-Fock Ab Initio Treatment of Crystalline Systems

Editors Prof. Dr. Gaston Berthier Prof. Dr. Hans H. Jaffe Universite de Paris Department of Chemistry Institut de Biologie University of Cincinnati Physico-Chimique Cincinnati, Ohio 452211USA Fondation Edmond de Rothschild 13, rue Pierre et Marie Curie F-75005 Paris Prof. Dr. Joshua Jortner Institute of Chemistry Prof. Dr. Michael J. S. Dewar Tel-Aviv University Department of Chemistry IL-61390 Ramat-Aviv The University of Texas Tel-Aviv/Israel Austin, Texas 78712/USA Prof. Dr. Hanns Fischer Physikalisch-Chemisches Institut Prof. Dr. Werner Kutzelnigg der Universitat ZOrich Lehrstuhl fOr Theoretische Chemie Ramistr.76 der Universitat Bochum CH-8001 ZOrich Postfach 102148 0-4630 Bochum 1 Prof. Dr. Kenichi Fukui Kyoto University Dept. of Hydrocarbon Chemistry Kyoto/Japan Prof. Dr. Klaus Ruedenberg Department of Chemistry Prof. Dr. George G. Hall Iowa State University 4 Westgate Court Ames, Iowa 50010/USA Highroad - Chilwell Nottingham NG9 4BT UK Prof. Dr. Jacopo Tomasi Prof. Dr. JOrgen Hinze Dipartimento di Chi mica e Fakultat fOr Chemie Chimica Industriale Universitat Bielefeld Universita di Pisa Postfach 8640 Via Risorgimento, 35 0-4800 Bielefeld 1-56100 Pisa Lecture Notes in Chemistry Edited by G. Berthier M.J.S. Dewar H. Fischer K. Fukui G. G. Hall J. Hinze H. H.J affe J. Jortner W. Kutzelnigg K. Ruedenberg J. Tomasi 48 C. Pisani R. Dovesi C. Roetti Hartree-Fock Ab Initio Treatment of Crystalline Systems Springer-Verlag Berlin Heidelberg New York London Paris Tokyo Authors C. Pisani R. Dovesi C. Roetti Dipartimento di Chimica Inorganica, Chimica Fisica e Chimica dei Materiali Universita di Torino Via Giuria 5,1-10125 Torino, Italy ISBN-13: 978-3-540-19317-3 e-ISBN-13: 978-3-642-93385-1 001: 10.1007/978-3-642-93385-1 This work is subject to copyright. All rights are reserved, whether the whole or part of the matenal is concerned, speCifically the rights of translation, reprinting, re-use of illustrations, recitation, broadcasting, reproduction on microfilms or in other ways, and storage in data banks. Duplication of this publication or parts thereof is only permitted under the proviSIOns of the German Copyright Law of September 9, 1965, In its version of June 24, 1985, and acopyright fee must always be paid. Violations fall under the prosecution act of the German Copyright Law © Springer-Verlag Berlin Heidelberg 1988 Foreword This book presents a computational scheme for calculating the electronic properties of crystalline systems at an ab-ini tio Hartree-Fock level of approximation. The first chapter is devoted to discussing in general terms the limits and capabilities of this approximation in solid state studies, and to examining the various options that are open for its implementation. The second chapter illustrates in detail the algorithms adopted in one specific computer program, CRYSTAL, to be submitted to QCPE. Special care is given to illustrating the role and in:fluence of computational parameters, because a delicate compromise must always be reached between accuracy and costs. The third chapter describes a number of applications, in order to clarify the possible use of this kind of programs in solid state physics and chemistry. Appendices A, B, and C contain various standard expressions, formulae, and definitions that may be useful for reference purposes; appendix D is intended to facilitate the interpretations of symbols, conventions, and acronyms that occur in the book. Thanks are due to all those who have contributed to the implementation and test of the CRYSTAL program, especially to V.R. Saunders and M. Causal, and to F. Ricca, E. Ferrero, R. Or lando, E. Ermondi, G. Angonoa, P. Dellarole, G. Baracco. The authors want to express their warmest gratitude to V.R. Saunders, one of the coauthors of CRYSTAL, for useful suggestions and the revision of part of the manuscript; to M. Causal, for his help in preparing a number of data tables, and for his contribution in the analysis of correlation corrections; to J. Tomasi, R. Orlando, and L. Salasco for the careful reading of the text. Many lengthy calculations have been expressly performed for this book, particularly for testing the influence of computational parameters on numerical accuracy and computer times: this has been made possible by generous contributions from the Consorzio per il Sistema Informativo Piemonte (CSI Piemonte). TABLE OF CONTENTS CHAPTER I. DIFFERENT APPROACHES TO THE STUDY OF THE ELECTRONIC PROPERTIES OF PERIODIC SYSTEMS 1.1 Many-electron systems: the viewpoint of theoretical chemists and physicists 1 1.2 A mosaic of options for the ab initio treatment of crystalline systems 5 a) Introduction b) Hamiltonians c) Basis sets d) Solution techniques e) An example: beryllium 1.3 Specific features of crystalline with respect to molecular Hartree-Fock computational schemes 13 a) HF schemes in solid state physics b) Basis set selection c) The treatment of Coulomb interactions d) The treatment of exchange interactions e) Sampling and integration in reciprocal space f) Exploitation of local symmetry 1.4 Overcoming the limitations of the all-electron HF perfect-crystal model 28 a) Introduction b) Pseudopotentials c) Correlation corrections d) Local defects in crystals CHAPTER II. IMPLEMENTATION OF THE HARTREE-FOCK EQUATIONS FOR PERIODIC SYSTEMS 11.1 Introductory remarks 34 11.2 Basis functions and charge distributions 35 a) Atomic orbitals, Bloch functions, and representation of operators b) Compact expressions for charge distributions 11.3 Basic equations 40 11.4 The Coulomb series and the Madelung problem a) General considerations b) Rearrangement of the Coulomb series: partition of the h space in a "bielectronic" and a "monoelectronic" zone c) Further partition of the bielectronic zone: the bipolar expansion v d) Further partition of the monoelectronic zone: the two center expansion e) Remarks and comments on the "partition and multipolar expansion scheme" f) On the evaluation of the integrals g) Evaluation of field and multipole integrals h) Integrals involving infinite summations i) Numerical examples on the Coulomb series 11.5 The exchange series 74 a) Introduction b) Long range behavior of the bond order matrix and influence on total energy and wave function c) Truncation criteria of the exchange series 11.6 Interpolation and integration in reciprocal space 86 a) Theory b) Examples of application 11.7 Symmetry properties 96 a) Local symmetry operators b) Transformation properties of the AOs c) Symmetry properties of the Bloch functions and of the COs d) Transformation properties of direct space integrals and matrices e) The irreducible set f) Sums of two electron integrals g) Multipole and field integrals h) Symmetry and SCF procedure. Fock matrix and energy expression 11.8 Choice of basis set and related problems 111 11.9 The CRYSTAL program 119 a) General scheme of the program b) Further considerations about the computational parameters c) SCF convergence d) Limits of applicability CHAPTER III. CALCULATION OF OBSERVABLE QUANTITIES IN THE HF APPROXIMATION 111.1 Energy and energy related quantities 125 a) General considerations b) Polyacetylene, as a test of accuracy of computational techniques c) Basis set and numerical accuracy effects: different crystalline phases of MgO d) The slab model in the study of surfaces and their adsorption properties: MgO (001) and (011) and Be (0001) crystal faces e) Formation energy of crystals: MgO, diamond, graphite and lithium VI III.2 Band structure and density of states (DOS) 144 a) One-electron HF levels and single particle excitation spectrum of crystals b) Projected DOSs and Mulliken populations c) Chemical information from band structure and DOSs: 3D and 2D systems III.3 Electron charge density and related quantities 150 a) Computational techniques and general considerations b) Total and difference electron charge density maps: beryllium, a-alumina c) Comparison of calculated and experimental x-ray structure factors: beryllium III.4 Electron Momentum Distribution (EMe) and related quantities 157 a) Computational techniques: Momentum density, Compton profiles (CP) and Autocorrelation function (AF) b) Momentum distribution properties: lithium and MgO c) Mulliken analysis of the AF: the case of MgO APPENDICES A. Solid harmonics and multi120lar eX12ansion of Coulomb interactions 169 B. Definition of Brillouin Zone and related quantities 172 C. The McMurchie-Davidson technique for the evaluation of the molecular integrals 174 Cl. Hermite gaussian type functions (HGTF) C2. The Gaussian product theorem and the expansion in HGTF C3. The expansion coefficients E a) Recursion in 2 b) Recursion in 2 and Iml = 2 c) Method of generation C4. Overlap and kinetic integrals C5. Nuclear attraction integrals C6. Two electron repulsion integrals D. Symbols and notations 182 REFERENCES 184 CHAPTER I. DIFFERENT APPROACHES TO THE STUDY OF THE ELECTRONIC PROPERTIES OF PERIODIC SYSTEMS 1.1 MANY-ELECTRON SYSTEMS THE VIEWPOINT OF THEORETICAL CHEMISTS AND PHYSICISTS It is the purpose of this book to present and discuss an ab initio Hartree-Fock (HF) scheme for the calculation of the electronic structure of crystalline systems. The techniques adopted are in a sense midway between those currently used in molecular quantum chemistry and those traditionally employed in solid state physics. In past years, the implementation of computer programs for the study of molecules and crystals has followed almost independent patterns, and the state of the art in the two fields of research presents markedly distinctive features, although the basic problem is the same: the study of a many-electron system in the Coulomb field of fixed nuclei. Theoretical chemists have succeeded in developing powerful, general purpose, universally adopted ab initio programs for molecules. Consider for instance GAUSSIAN-82 (Binkleyet al 1981), the newborn of a family of high-quality molecular programs developed by Pople and coworkers during almost twenty years' work, and which may be obtained on request from Prof. Pople at the Carnegie-Mellon University, Pittsburgh, Pennsylvania. It is primarily designed for users interested in applications of quantum chemistry methods rather than in the calculation itself; the input is therefore extremely easy, and the output is self-explanatory. Its capabilities include: 1. calculation of one- and two-electron integrals over atomic orbitals; 2. Self-Consistent Field (SCF)-HF calculations for closed- and open-shell molecular systems; 3. evaluation of one-electron properties of the HF wavefunction; 4. automated geometry optimization of the molecule, and calculation of force constants; 5. harmonic vibrational analysis; 6. correlation energy calculated by using one of the following choices: configuration interaction, M~ller-Plesset perturbation theory or coupled cluster techniques. GAUSSIAN-82 is by no means tbe only ab initio program in current use for the calculation of molecular properties. However, the computational schemes that have proved most successful use essentially the same ingredients: the linearized HF-Roothaan equations are solved, by using as a basis set a small number of atomic orbitals (AO) per atom; in turn, the AOs are expressed as a linear combination of gaussian type orbitals (GTO), or primitives, with appropriate exponent coefficients and "contraction" coefficients; after obtaining the molecular orbitals (MO), eigenvectors of the Fock matriX, through a SCF procedure, the correlation correction to the ground state wavefunction and properties and the description of excited states is usually performed by means of configuration interaction (CI) or 2 perturbation techniques. In all cases much ingenuity has been spent in making the use of these programs as easy and transparent as possible in spite of their enormous complexity. The sequence of steps that has finally led to these accurate and reliable machines for the solution of the molecular problem is brilliantly reconstructed in a recent booklet by Schaefer (1985). A posteriori, theoretical quantum chemistry appears to have followed quite a linear path, with a substantial concentration of efforts, from the original formulation of the HF equations (Fock 1930, Slater 1930) to their linearized expression by Roothaan (1951), from Boys' (1950 a, 1950 b, 1956) anticipation of present day techniques, to their full realization; this has implied, e.g., the selection of standard basis sets of assessed efficiency (Clementi and Roetti 1974, Huzinaga 1984), the development of powerful integration techniques (Shavitt 1963, McMurchie and Davidson 1978), the efficient handling of hundreds of thousand configurations in CI calculations (Nesbet 1963, Yoshimine 1973, Saunders and van Lenthe 1983) and the appearance of new fruitful ideas for the treatment of the correlation problem (Cizek 1966, Krishnan et al 1980, Guest and Wilson 1980). In his comment on Barnett's ( 1963) paper introducing the POLYATOM program, Schaefer (1985) writes: "Visionaries have for some years imagined a futuristic 'black box' computer program, to which the bench chemist specifies a desired molecule and a series of properties of interest. After a few moments of cogitation, the computer politely returns the answers, reliable to specified tolerances". With all the risks of improper use or sheer misuse of these powerful instruments, the present situation is not too far from that vision, wi th regard to the HF solution and the corresponding one-electron properties, and if small molecules not containing heavy atoms are considered. In comparison with the situation described above, a much greater variety of techniques are currently employed for the description of the electronic properties of crystals, resulting in much less standardization. This is so for both intrinsic and historical reasons. Much of the theory of molecules and molecular reactivity can be constructed from information concerning the ground state and its total energy. The primary aim of molecular quantum chemistry is therefore understanding the reasons for the stability of certain aggregates of atoms, and predicting how the binding energy depends on the geometrical arrangement of the nuclei. In this respect, the preference of theoretical chemists for the HF approximation is easily understood, since, it provides, in a variational sense, the best monoelectronic approximation for the ground state, that is the single determinant wave function with the lowest expectation value for energy. On the contrary, the problem of crystal stability is not of primary importance in solid state physics, at least when chemically simple crystalline compounds are considered, such as elemental or binary compounds. As a rule, these kinds of crystal are well characterized and they can generally be classified rather accurately, according to one of a few selected categories. For each of them, well established empirical or semi-empirical schemes exist for correlating crystal structure and stability with the chemical nature of the atoms involved (O'Keeffe and Navrotsky 1981); in many instances, especially in ionic 3 systems, the binding energy can be calculated with high accuracy using sui tably optimized two-body potentials (Catlow and Mackrodt 1982). Only recently has attention been given to complicated crystalline systems where structural predictions are difficult, and where interesting solid-solid phase transitions or chemical reactions can occur. For these reasons, the problem of describing the ground state of real crystals and calculating its energy has historically not been the object of much concern for solid state physicists. This attitude is well expressed by the following excerpt from a recent book by Inkson (1984): " When considering how to describe an interacting system, we should be very clear what it is we require. First of all, it will not be useful to consider the ground state; it will almost certainly be a highly complicated object and, apart perhaps from its formation energy from some other state, of very little interest. What we are normally interested in is what happens to the system when it is disturbed, by some experimental probe for instance. What is required then, are expectation values of operators, transitions between states, time development in particular circumstances, etc.". These kind of phenomena are however very difficult to account for satisfactorily ab initio, that is, only from the knowledge of the atomic number and geometrical arrangement of the nuclei, and using the basic quantum mechanical equations. An extraordinary variety of approaches has therefore flourished in solid state physics: a wide spectrum of sophisticated mathematical tools are employed, specific hamiltonians are used for the different problems, and the real systems under investigation are described according to different models. Two prototype schemes emerge due to their simplicity and importance: the homogeneous electron gas and the tight binding (TB) model. The homogeneous electron gas has attracted enormous attention, as a prototype of condensed many-electron systems, as a good model for the response properties of simple metals, and as a necessary reference point for the treatment of periodic non-homogeneous systems (Lundqvist and March 1983). Some of the peculiarities of present day solid state physics with respect to molecular quantum mechanics can probably be traced back to the central role assumed by the electron gas problem in the former case. First, the HF approximation performs unsatisfactorily here. The binding energy of the system is grossly underestimated; still more important, the distribution of the one-electron energies associated with the HF canonical orbitals (plane waves, in this case) does not provide reliable information on the spectrum of single electron excitation energies. In particular, the density of states of the electron gas as obtained from HF calculations is zero at the Fermi energy: this unphysical feature, related to the nature of the "bare" exchange operator is preserved in all cases, when rigorous HF calculations for metallic systems are performed (Monkhorst,1979). These failures are probably at the root of the deep mistrust of solid state physicists with regard to HF approaches. Second, the use of plane waves (PW) or augmented plane waves (APW) as a flexible and universal basis set appears nearly mandatory if the electron gas has to be included as a limiting case among the systems to be treated; localized basis functions, such as the AOs used in molecular quantum chemistry seem quite inadequate for this purpose. Third, the homogeneous electron gas is the natural reference point and the exact limiting case for density-functional (DF) theories {Hohenberg and Kohn

Description:
This book presents a computational scheme for calculating the electronic properties of crystalline systems at an ab-ini tio Hartree-Fock level of approximation. The first chapter is devoted to discussing in general terms the limits and capabilities of this approximation in solid state studies, and t
See more

The list of books you might like

Most books are stored in the elastic cloud where traffic is expensive. For this reason, we have a limit on daily download.