WATER AND AQUEOUS SOLUTIONS Introduction to a Molecular Theory WATER AND AQUEOUS SOLUTIONS Introduction to a Molecular Theory Arieh Ben-Nairn Institute of Chemistry The Hebrew University of Jerusalem Jerusalem, Israel PLENUM PRESS • NEW YORK AND LONDON Library of Congress Cataloging in Publication Data Ben-Na'im, Aryeh. Water and aqueous solutions. Bibliography: p. 1. Solution (Chemistry) 2. Water. 3. Molecular theory. I. Title. QD541.B46 546'.22 74-7325 ISBN-13: 978-1-4615-8704-0 e-ISBN-13: 978-1-4615-8702-6 001: 10.1007/978-1-4615-8702-6 Acknowledgments Thanks are due to the following for permission to reproduce figures from their publications: D. Eisenberg and W. Kauzmann (Figs. 6.4, 6.5, 6.6); A. H. Narten and H. A. Levy (Figs. 6.7,6.10); A. Rahman and F. H. Stillinger (Figs. 6.32, 6.33); J. A. Barker and R. O. Watts (Fig. 6.30); North-Holland Publishing Company (Figs. 6.19, 6.30,8.23); The Journal of Chemical Physics (Figs. 1.3, 5.2, 5.4, 5.5,5.6, 5.7, 5.8, 5.9, 6.2,6.7,6.9,6.14,6.18,6.19,6.20,6.21,6.22,6.24, 6.25, 6.26, 6.27, 6.28, 6.29, 6.31,6.32,6.33,8.1,8.4,8.7,8.8,8.12,8.13,8.15, 8.17, 8.18); The Clarendon Press, Oxford (Figs. 6.4,6.5,6.6); The Journal of Solution Chemistry (Figs. 7.4, 7.5,7.6, 8.11,8.20,8.21,8.22); Molecular Physics (Taylor and Francis, Ltd.) (Figs. 6.21, 6.23); Chemical Physics Letters (6.19,6.30,8.23); J. Wiley and Sons, Inc. (Figs. 2.6, 2.7,2.8,4.3,6.13,6.14, 7.1,7.2>' @ 1974 Plenum Press, New York A Division of Plenum Publishing Corporation 227 West 17th Street, New York, N.Y. 10011 United Kingdom edition published by Plenum Press, London A Division of Plenum Publishing Company, Ltd. 4a Lower John Street, London WIR 3PD, England All rights reserved No part of this book may be reproduced, stored in a retrieval system, or trans mitted, in any form or by any means, electronic, mechanical, photocopying, microfilming, recording, or otherwise, without written permission from the Publisher Dedicated to Talma Preface The molecular theory of water and aqueous solutions has only recently emerged as a new entity of research, although its roots may be found in age-old works. The purpose of this book is to present the molecular theory of aqueous fluids based on the framework of the general theory of liquids. The style of the book is introductory in character, but the reader is presumed to be familiar with the basic properties of water [for instance, the topics reviewed by Eisenberg and Kauzmann (1969)] and the elements of classical thermodynamics and statistical mechanics [e.g., Denbigh (1966), Hill (1960)] and to have some elementary knowledge of probability [e.g., Feller (1960), Papoulis (1965)]. No other familiarity with the molecular theory of liquids is presumed. For the convenience of the reader, we present in Chapter 1 the rudi ments of statistical mechanics that are required as prerequisites to an under standing of subsequent chapters. This chapter contains a brief and concise survey of topics which may be adopted by the reader as the fundamental "rules of the game," and from here on, the development is very slow and detailed. Excluding the introductory chapter, the book is organized into three parts. The first, Chapters 2-4, presents the general molecular theory of fluids and mixtures. Here the notions of molecular distribution functions are developed with special attention to fluids consisting of nonspherical particles. We have included only those theories judged to be potentially useful in the study of aqueous fluids, so this part may not be considered as an introduction to the theory of fluids per se. With this objective in mind we did not survey the recent developments in the theory of simple fluids. Instead we present ample illustrative examples vii viii Preface to stress the contrast between simple fluids, on one hand, and the more complex, aqueous fluids on the other. Of course, the particular choice of topics is a matter of personal taste and has no absolute significance. For instance, the theory of solutions may be developed either along the Mc Millan-Mayer (1945) theory or along the Kirkwood-Buff (1951) theory. Both are exact and equivalent from the formal point of view. However, the latter is judged to be the more suitable for problems arising in the theory of aqueous fluids. The second part consists of Chapter 5 alone, which comprises a bridge connecting the formal theory of fluids, on the one hand, and its application to water and aqueous solutions on the other. The construction of this bridge is rendered possible through the generalization of the ideas of mo lecular distribution functions, which lays the foundation for the so-called mixture-model approach to the theory of fluids. The latter may be viewed as the formal basis for various ad-hoc mixture models for water and aqueous solutions that have been suggested by many authors. The third part, Chapters 6-8, presents the treatment of essentially three systems, namely pure water with zero, one, and two simple solutes, respectively. Chapter 6 includes a brief survey of the properties of water. We have avoided excessive duplication of material which has been fully discussed by Eisenberg and Kauzmann (1969). The emphasis is mainly on the various theoretical approaches, both old and of recent origin, to explain the anomalous properties of this unique fluid. Chapter 7 is con cerned with very dilute solutions of simple nonelectrolytes which, from the formal point of view, reflect the properties of pure water with a single solute particle. Both experimental facts and theoretical attempts at inter pretation are surveyed. Special attention is devoted to elaboration on the exact meaning and significance of "structural changes" induced by a solute on the solvent. The last chapter deals with small deviations from very dilute solutions. The problem of hydrophobic interaction, considered to be of crucial importance in biochemical processes, is formulated, and methods of es timating the strength of solute-solute interaction in various solvents are discussed. Preliminary attempts at interpretation, based on concepts de veloped in the preceding chapters, are also surveyed. Although the framework of this book could have easily accommodated a chapter on ionic solutions we chose not to include this topic, as several works already exist dealing with it exclusively. The entire subject of aqueous solutions is still subject to vigorous debate, and many approaches, theories, and interpretations are highly Preface ix controversial. We have expended a mild effort to represent a reasonable spectrum of opinions advanced by various authors. However, a book on such a subject must inevitably reflect the author's own bias. The common thread linking the subject matter included in Chapters 5-8 is the application of the mixture-model approach to the theory of fluids. It is the author's opinion that this theoretical tool is particularly useful in treating aqueous fluids and, hopefully, will help us to understand these systems on both the molecular and the macroscopic levels. I am very much indebted to many friends and colleagues who encour aged me in undertaking the writing of this book. Thanks are due to Drs. R. Battino, D. Henderson, H. S. Frank, A. Nitzan, D. Shalitin, F. H. Stillinger, and R. Tenne for reading parts of the manuscript and kindly offering helpful comments and suggestions. Arieh Ben-Nairn Jerusalem, Israel Contents Chapter 1. Introduction and Prerequisites 1.1. Introduction 1.2. Notation. . 2 1.3. Classical Statistical Mechanics 6 1.4. Connections between Statistical Mechanics and Thermo- dynamics 9 1.4.1. T, V, N Ensemble 9 1.4.2. T, P, N Ensemble 10 1.4.3. T, V, p, Ensemble 10 1.5. Basic Distribution Functions in Classical Statistical Mechanics 13 1.6. Ideal Gas . . . . . . . . . . . . . 15 1. 7. Pair Potential and Pairwise Additivity 17 1.8. Virial Expansion and van der Waals Equation 25 Chapter 2. Molecular Distribution Functions 29 2.1. Introduction . . . . . . . . . . 29 2.2. The Singlet Distribution Function 30 2.3. Pair Distribution Function 36 2.4. Pair Correlation Function . 39 xi xii Contents 2.5. Features of the Radial Distribution Function 43 2.5.1. Ideal Gas 44 2.5.2. Very Dilute Gas . . . . . . . . . . . . 45 2.5.3. Slightly Dense Gas . . . . . . . . . . . 45 2.5.4. Lennard-Jones Particles at Moderately High Densities. 49 2.6. Further Properties of the Radial Distribution Function 53 2.7. Survey of the Methods of Evaluating g(R) 65 2.7.1. Experimental Methods. 65 2.7.2. Theoretical Methods. . . . . . . 68 2.7.3. Simulation Methods. . . . . . . 69 2.8. Higher-Order Molecular Distribution Functions 75 2.9. Molecular Distribution Functions (MDF) in the Grand Ca- nonical Ensemble. . . . . . . . . . . . . . . 78 Chapter 3. Molecular Distribution Functions and Ther r.nodynar.nics . . . . . . . . . . . . . . . .. 81 3.1. Introduction . . . . . . . . . . . . 81 3.2. Average Values of Pairwise Quantities 82 3.3. Internal Energy. . . . 85 3.4. The Pressure Equation . . 88 3.5. The Chemical Potential . . 91 3.6. Pseudo-Chemical Potential . 99 3.7. Entropy . . . . . . . . . 101 3.8. Heat Capacity . . . . . . 102 3.9. The Compressibility Equation 104 3.10. Local Density Fluctuations 109 3.11. The Work Required to Form a Cavity in a Fluid. 114 3.12. Perturbation Theories of Liquids. . . . . . . . 120 Chapter 4. Theory of Solutions 123 4.1. Introduction . . . . . . . . . 123 4.2. Molecular Distribution Functions in Mixtures; Definitions. 124 4.3. Molecular Distribution Functions in Mixtures; Properties. 127 Contents xiii 4.4. Mixtures of Very Similar Components. . . . . . . . . .. 135 4.5. The Kirkwood-Buff Theory of Solutions. . . . . . . . .. 137 4.6. Symmetric Ideal Solutions; Necessary and Sufficient Conditions 145 4.7. Small Deviations from Symmetric Ideal (SI) Solutions 153 4.8. Dilute Ideal (DI) Solutions. . . . . . . . . 155 4.9. Small Deviations from Dilute Ideal Solutions 159 4.10. A Completely Solvable Example . . . . . . 164 4.10.1. Ideal Gas Mixture as a Reference System. . 167 4.10.2. Symmetric Ideal Solution as a Reference System 167 4.10.3. Dilute Ideal Solution as a Reference System. . 168 4.11. Standard Thermodynamic Quantities of Transfer 170 4.11.1. Entropy. 174 4.11.2. Enthalpy. 176 4.11.3. Volume . 176 Chapter 5. Generalized Molecular Distribution Functions and the Mixture-Model Approach to Liquids 177 5.1. Introduction 177 5.2. The Singlet Generalized Molecular Distribution Function 179 5.2.1. Coordination Number (CN). 180 5.2.2. Binding Energy (BE) 183 5.2.3. Volume of the Voronoi Polyhedron (VP). 184 5.2.4. Combination of Properties 186 5.3. Illustrative Examples of GMDF's 187 5.4. Pair and Higher-Order GMDF's . 194 5.5. Relations between Thermodynamic Quantities and GMDF's 195 5.5.1. Heat Capacity at Constant Volume . 197 5.5.2. Heat Capacity at Constant Pressure. 198 5.5.3. Coefficient of Thermal Expansion. 200 5.5.4. Isothermal Compressibility 200 5.6. The Mixture-Model (MM) Approach; General Considerations 201 5.7. The Mixture-Model Approach to Liquids; Classifications Based on Local Properties of the Molecules . 208 5.8. General Relations between Thermodynamics and Quasicom- ponent Distribution Functions (QCDF) . 211