Advances CHEMICAL PHYSICS - download.e-bookshelf.de fileEDITORIAL BOARD C. J. BALLHUSEN, Kobenhaven Universitets Fysisk-Kemiske Institut. Kemisk BRUCE BERNE, Depatment of Chemistry,

Advances in CHEMICAL PHYSICS

VOLUME LIX

INDEX: VOLUMES I-LV

PREPARED BY

Patricia L. Radloff The James Franck Institute The University of Chicago

Chicago, Illinois

SERIES EDITORS

I. PRIGOGINE

University of Brussels Brussels, Belgium

and University of Texas

Austin. Texas

AND

STUART A. RICE

Department of Chemistry and

The James Franck Institute The University of Chicago

Chicago. Illinois

AN INTERSCIENCE'" PUBLICATION JOHN WILEY & SONS

NEW YORK CHICHESTER BRISBANE TORONTO SINGAPORE

ADVANCES IN CHEMICAL PHYSICS

VOLUME LIX

EDITORIAL BOARD

C. J . BALLHUSEN, Kobenhaven Universitets Fysisk-Kemiske Institut. Kemisk

BRUCE BERNE, Depatment of Chemistry, Columbia University, New York, N.Y.,

RICHARD B. BERNSTEIN, Department of Chemistry, University of California, Los

G. CARER], Instituto di Fisica “Guglielmo Marconi.” Universita delli Studi, Piazzle

MORREL COHEN, Exxon Research and Engineering Company, Clinton Township,

KARL E FREED, The James Franck Institute, The University of Chicago, Chicago,

ROBERT GOMER. The James Franck Institute, The University of Chicago, Chicago,

RAYMOND E. KAPRAL, University of Toronto, Toronto, Ontario, Canada WILLIAM KLEMPERER, Department of Chemistry, Harvard University, Cambridge,

YU L. KLIMONTOVITCH, Moscow State University, Moscow, USSR V. KRINSKI, Institute of Biological Physics, USSR Academy of Science. Puschino,

M. MANDEL, Chemie-Complex der Rijks-Universiteit, Wassenaarseweg, Leiden,

RUDY MARCUS, Department of Chemistry, California Institute of Technology,

PETER MAZUR, Institute Lorentz voor Theoretische Natuurkunde, Nieuwsteeg.

GRECOIRE NICOLIS, Pool de Physique, Faculte dc Sciences, Universite Libre de

A. PACAULT, Centre de Recherches Paul Pascal, Domaine Universitaire, Talance.

YVES POMEAU, Commissariat a I’Energie Atomique, Centre d’Etudes nucleaires de

A. RAHMAN, Argonne National Laboratory, Argonne, Illinois, U S A . I? SCHUSTER, Institut fur Theoretische Chemie und Strahlenchemie, Universita

1. SHAVITT, Department of Chemistry, Ohio State University, Columbus, Ohio,

KAZUHISA TOMITA. Department of Physics, Faculty of Science, Kyoto University,

Laboratorium IY Kobenhaven, Denmark

U.S.A.

Angeles, California. U.S.A.

delle Scienze, Rome, Italy

Annandale, New Jersey, U.S.A.

Illinois, U.S.A.

Illinois, U S A .

Massac huse tts, U.S. A.

Moscow Region. USSR

Netherlands

Pasadena, California, U.S.A.

Leiden, Netherlands

Bruxelles. Bruxelles, Belgium

France

Saclay, Division de la Physique, Gif-sur-Yvette, France

Wien, Wien, Austria

U.S.A.

Kyoto, Japan

Advances in CHEMICAL PHYSICS

VOLUME LIX

INDEX: VOLUMES I-LV

PREPARED BY

Patricia L. Radloff The James Franck Institute The University of Chicago

Chicago, Illinois

SERIES EDITORS

I. PRIGOGINE

University of Brussels Brussels, Belgium

and University of Texas

Austin. Texas

AND

STUART A. RICE

Department of Chemistry and

The James Franck Institute The University of Chicago

Chicago. Illinois

AN INTERSCIENCE'" PUBLICATION JOHN WILEY & SONS

NEW YORK CHICHESTER BRISBANE TORONTO SINGAPORE

An Interscience@ Publication

Copyright 0 1985 by John Wiley &Sons, Inc.

All rights reserved. Published simultaneously in Canada.

Reproduction or translation of any part of this work beyond that permitted by Section 107 or 108 of the 1976 United States Copyright Act without the permission of the copyright owner is unlawful. Requests for permission or further information should be addressed to the Permissions Department, John Wiley & Sons, Inc.

Library of Congress Catalog Number: 58-9935 ISBN 0-471-80427-4

Printed in the United States of America

1 0 9 8 7 6 5 4 3 2 1

ARTICLE INDEX

AUTHOR INDEX

SUBJECT INDEX

CONTENTS

1

35

59

ADVANCES IN CHEMICAL PHYSICS

VOLUME LIX

ARTICLE INDEX

A Alcohol narcosis

Johnson, F. H., “Hydrostatic Pres- sure Reversal of Alcohol Narcosis in Aquatic Animals,” 21:647.

McGowan, J . W., Kummler, R . H., and Gilmore, F. R., “Excitation De-excitation Processes Relevant to the Upper Atmosphere,” 28: 3 79.

Michels, H. H., “Electronic Excited States of Selected Atmospheric Systems,” 45:225.

Nicolet, M., “Atmospheric Chemis- try,” 5563.

Zander, R., “Commentary: Observa- tional Aspects Related to the Chemical Evolution of Our Atmosphere,” 55:79.

Atmospheric chemistry

BCnard convection see Convection

Benzenes Goodman, L. and Rava, R. P., “Two-

Photon Spectroscopy of Per- turbed Benzenes,” 54: 177.

Parmenter, C. S., “Radiative and Nonradiative Processes in Ben- zene,” 22:365.

see also Electronic spectroscopy

Kauffman, S. A,, “Bifurcations in Insect Morphogenesis,” 55:2 19.

Nicolis, G., “Bifurcations and Sym- metry Breaking in Far-from-Equi- librium Systems: Toward a Dynamics of Complexity,” 55: 177.

Bifurcations

Biomolecule conformation Uny, D. W., “Biomolecular Confor-

mation and Biolo&al Activity,” 21:581.

Boron Houtman, J. A. and Duffey, G. H.,

“A Free-Electron Study of Com- mon Boron Frameworks,” 21:7.

Dagonnier, R.. “Theory of Quantum Brownian Motion,” 16: 1.

Guth, E., “Brownian Motion and Inde te rminacy Rela t ions ,” 15:363.

Brownian motion

1

2 ADVANCES IN CHEMICAL PHYSICS

C Carcinogenesis

Daudel, R., “The Relation Between Structure and Chemical Reac- tivity of Aromatic Hydrocarbons with Particular Reference to Car- cinogenic Properties,” l: 165.

Pullman, B., “Steroids, Purine- Pyrimidine Pairs and Polycyclic Aromatic Carcinogens,” 8: 163.

Comer, R., “Electron Spectroscopy of Chemisorption on Metals,” 21:2 I I .

Bernasek, S. L., “Heterogeneous Reaction Dynamics,” 41:477.

Hammes, G. G., “Control ofthe Cat- alytic Activity of Enzymes by the Near and Remote Environment of a Polyatomic Framework,” 39: 177.

Higuchi, I.. “The Pore Structure of Catalysts and Catalytic Reaction Rates,” 21:79 1.

Klotz, 1. M., “Synzymes: Synthetic Polymers with Enzymelike Cata- lytic Activities,” 39: 109.

Laforgue, A., Rousseau, J., and Imelik, B., “Chemisorption of Ethylene on Metals and Catalytic Hydrogenation,” 8: 14 I .

Catalysis

Chaos Brumer, P., “Intramolecular Energy

Transfer: Theories for the Onset of Statistical Behavior,” 47:Part 1:201.

Ford, J., “The Transition from Ana- lytic Dynamics to Statistical Mechanics.” 24: 155.

Kauffman, S. A,, “Bifurcations in Insect Morphogenesis,” 5 5 2 19.

Percival, I . C., “Semiclassical Theory

of Bound States,” 36: I . Rice, S. A., “An Overview of the

Dynamics of Intramolecular Transfer of Vibrational Energy,” 47:Part 1 : I 17.

Tabor, M., “The Onset of Chaotic Motion in Dynamical Systems,” 46:73.

Charge transfer Baede, A. P. M., ”Charge Transfer

Between Neutrals at Hyperther- ma1 Energies,” 30:463.

Englman, R., “Optical Absorptions and Charge Transfer States,” 8: 13.

Lichten, W., “Resonant Charge Exchange in Atomic Collisions,” 13:4 1 .

Stebbings, R. F., “Charge Transfer,” 10: 195.

w e ulso Collisional processes Chemical bonding

see Valence theory Chemical Dynamics

Adelman, S. A., “Chemical Reaction Dynamics in Liquid Solution,” 53:6 I .

Adelman, S. A , , “Generalized Langevin Equations and Many- body Problems in Chemical Dynamics,” 44: 143.

Anderson, J. B., “The Reaction F +

Aroeste, H., “Toward an Analytic Theory of Chemical Reactions,” 6:l.

Atkins, P. W. and Evans, G. T., “Theories of Chemically Induced Electron Spin Polarization,” 35: I .

Baede, A. P. M., “Charge Transfer Between Neutrals at Hyperther- ma1 Energies,” 30:463.

Baer, M., “A Review of Quantum- Mechanical Approximate Treat-

H2 + HF + H,” 41~229.

ARTICLE INDEX 3 ments of Three-Body Reactive Systems,” 49: 19 1.

Balint-Kurti, G. G., “Potential Energy Surfaces for Chemical Reaction,” 30: 137.

Baronavski, A., Umstead, M. E., and Lin, M. C., “Laser Diagnostics of Reaction Product Energy Distri- butions,” 47:Part 2:85.

Baniol, J. and Regnier, J., “Calcula- tion of Transition Energies from the Geometry of the System,” 8:s.

Basilevsky, M. V., “Transition State Stabilization Energy as a Measure of Chemical Reactivity,” 33:345.

Bass, L. B. and Moore, W. J., “The- ory of Rate Processes Applied to Release of Acetylcholine at Synapses,” 21:6 19.

Ben-Shad, A., “Chemical Laser Kinetics,” 47:Part 255.

Bernasek, S. L., “Heterogeneous Reaction Dynamics,” 4 1 :477.

Beswick, J. A. and Jortner, J., “Intra- molecular Dynamics of van der Waals Molecules,” 47:Part 1 :363.

Bigeleisen, J. and Wolfsberg, M., “Theoretical and Experimental Aspects of Isotope Effects in Chemical Kinetics,” I : 15.

Caren, G., “Some Physical Aspects of Gaseous Chemical Kinetics,” 1:119.

Dewar, M. J. S., “Chemical Reac- tivity,” 8:65.

Eschenroeder, A. Q., “Reaction Kinetics in Hypersonic Flows,” 13:19.

Eyring, E. M., Rich, L. D., McCoy, L. L., Graham, R. C., and Taylor, N., “Activation Parameters and Deprotonat ion Kinetics of In t ramolecular ly Hydrogen Bonded Acids,” 21:327.

Grice, R., “Reactive Scattering,” 30:247.

Haas, Y., “Electronically Excited Fragments Formed by Unimolec- ular Multiple Photon Dissocia- tion,” 47:Part 1 :7 13.

Haas, Y. and Asscher, M., “Two- Photon Excitation as a Kinetic Tool: Application to Nitric Oxide F luorescence Quench ing ,” 47:Part 2: 17.

Herschbach, D., “Reactive Scattering in Molecular Beams,” 10:3 19.

Johnston, H. S, “Large Tunnelling Corrections in Chemical Reaction Rates,” 3: I3 I .

Kapral, R., “Kinetic Theory of Chemical Reactions in Liquids,” 48:7 1.

Keck, J. C., “Variational Theory of Reaction Rates,” 13:85.

Kreevoy, M. M. and Konasewich, D. E., “The Br~nsted a and the Pri- mary Hydrogen Isotope Effect. A Test of the Marcus Theory,” 21:243.

Laidler. K. J. and Tweedale, A., “The Current Status of Eyring’s Rate Theory,” 2 1 : 1 1 3.

Leone, S. R., “Photofragment Dynamics,” 50:255.

Levine, R. D., “The Information Theoretic Approach to Intramo- lecular Dynamics,” 47:Part 1:239.

Light, J. C., “Quantum Theories of Chemical Kinetics,” 19: I .

Lin, M. C., “Dynamics of Oxygen Atom Reactions,” 42: I 13.

Mahan, B. H.. “Recombination of Gaseous Ions,” 23: 1 .

McGowan, J. W., Kummler, R. H., and Gilmore, F. R., “Excitation De-excitation Processes Relevant to the Upper Atmosphere,”


28:379. McQuame, D. A., “Stochastic The-

ory of Chemical Rate Processes,” 15149.

Menziger, M., “Electronic Chemi- luminescence in Gases,” 42: I .

Micha, D. A., “Quantum Theory of Reactive Molecular Collisions,” 30:7.

Montroll, E. W. and Shuler, K. E., “The Application of the Theory of Stochastic Processes to Chemical Kinetics,” 1:361.

Mortensen, E. M., “Permeabilities for Reactions ofthe Type H + Hz = Hz + H Treated as a Linear Encounter Using Variational and Distorted Wave Techniques,” 21:127.

Nicolet, M., “Atmospheric Chemis- try,” 5563.

Smith, I. W. M., “The Production of Excited Species in Simple Chemi- cal Reactions.” 28: 1.

Welge, K. H. and Schmiedl, R., “Doppler Spectroscopy of Pho- tofragments,” 47:Part 2: 133.

Widom, B., “Collision Theory of Chemical Reaction Rates,” 5355.

Chemical kinetics

Chemilurninescence see Chemical dynamics

Menziger, M., “Electronic Chemi- luminescence in Gases,” 42: 1.

Comer, R., “Electron Spectroscopy of Chemisorption on Metals,” 27:2 1 1.

Laforgue, A,, Rousseau, J. , and Imelik, B., “Chemisorption of Ethylene on Metals and Catalytic Hydrogenation,” 8: 14 1.

Chemisorption

Chirality

Hansen, A. H. and Bouman, T. D., “Natural Chiroptical Spectros- copy: Theory and Computa- tions,” 44545.

Noyes, R. M., “Commentary: On Selection of Chirality,” 55: I 1 I .

Kaufmann, K. J. and Wasielewski, M. R., “Studies of Chlorophyll in Vitro,” 47:Part 2579.

Chlorophyll

Clathrates van der Waals, J . H. and Platteeuw, J .

C., “Clathrate Solutions,” 2: 1 .

Hoare, M. R., “Structure and Dynamics of Simple Microclus- ten,” 40:49.

Ng, C. Y., “Molecular Beam Pho- toionization Studies of Molecules and Clusters,” 52263.

Clusters

Coherence effects Cantrell, C. D., Makarov, A. A., and

Louisell, W. H.. “Laser Excitation of SF6: Spectroscopy and Coher- ent Pulse Propagation Effects,” 47:Part 1:583.

Wiersma, D. A,, “Coherent Optical Transient Studies of Dephasing and Relaxation in Electronic Transitions of Large Molecules in Condensed Media,” 47:Part 2:42 1.

Collisional processes Amme, R. C., “Vibrational and

Rotational Excitation in Gaseous Collisions,” 28: 17 I .

Baede, A. P. M., “Charge Transfer Between Neutrals at Hyperther- ma1 Energies,” 30:463.

Bak, T. A. and Sorensen, G. P., “Vibrational Relaxation of a Gas of Diatomic Molecules,” 1 5 2 19.

Birnbaum, G., Guillot, B., and Bra-

ARTICLE INDEX 5

tos, S., “Theory of Collision- Induced Line Shapes-Absorp- tion and Light Scattering at Low Density,” 51:49.

Breckenridge, W. H. and Umemoto, H., “Collisional Quenching of Electronically Excited Metal Atoms,” 50:325.

Brunner, T. A. and Pritchard, D., “Fitting Laws for Rotationally Inelastic Collisions,” 50:589.

Clark, A. P., Dickinson, A. S. and Richards, D., “The Correspond- ence Principle in Heavy-Particle Collisions,” 36:63.

DePristo, A.E. and Rabitz, H., “Vibrational and Rotational Col- lision Processes,” 42:27 I .


Freed, K. F., “Collision Induced Intersystem Crossing,” 47:Part 2:29 1.

Freed, K. F., “Collisional Effects on Electronic Relaxation Processes,” 42:207.

Frommhold, L., “Collision-Induced Scattering of Light and the Dia- tom Polarizabilities,” 46: l .

Haas, Y ., “Electronically Excited Fragments Formed by Unimolec- ular Multiple Photon Dissocia- tion,” 47:Part 1 :7 13.

Hertel, I. V., “Collisional Energy- Transfer Spectroscopy with Laser- Excited Atoms in Crossed Atom Beams: A New Method for Inves- tigating the Quenching of Elec- tronically Excited Atoms by Molecules,” 45:34 I .

Kempter, V., “Electronic Excitation in Collisions between Neutrals,” 30:4 17.

Kodaira, M. and Watanabe, T., “Col-

lisional Transfer of Triplet Excita- tions Between Helium Atoms,” 21:167.

Lacmann, K., “Collisional Ioniza- tion,” 42:5 13.

Lichten, W., “Resonant Charge Exchange in Atomic Collisions,” 13:41.

Micha, D. A,, “Quantum Theory of Reactive Molecular Collisions,” 30:7.

Miller, W. H., “Classical-Limit Quantum Mechanics and the Theory of Molecular Collisions,” 2569.

Miller, W. H., “Classical S-Matrix in Molecular Collisions,” 30:77.

Muschlitz, E. E., Jr., “Collisions of Electronically Excited Atoms and Molecules,” 10: 17 1.

Niehaus, A., “Spontaneous Ioniza- tion in Slow Collisions,” 45:399.

Nikitin, E. E., “Theory of Nonadia- batic Collision Processes Includ- ing Excited Alkali Atoms,” 28:3 17.

Rice, S. A., “Collision Induced Intra- molecular Energy Transfer in Electronically Excited Pol yatomic Molecules,” 47:Part 2:237.

Stebbings, R. F., “Charge Transfer,” 10: 195.

Tramer, A. and Nitzan, A., “Colli- sional Effects in Electronic Relax- ation,” 47:Part 2:337.

Widom, B., “Collision Theory of Chemical Reaction Rates,” 5355.

see also Energy transfer; Nonradia- tive processes; Vibrational relaxation

Convection Hurle, D. T. J . and Jakeman, E., “On

the Nature of Oscillatory Convec- tion in Two-Component Fluids,”


32:277. Koschmieder, E. L., “BCnard Con-

vection,” 26: 177. Koschmieder, E. L., “Stability of

Supercritical BCnard Convection and Taylor Vortex Flow,” 32: 109.

Moore, D. R., “Numerical Models for Convection,” 32:65.

Morgan, J. C., “The Effect of Prandtl Number on Finite Amplitude Bknard Convection,” 32:77.

Platten, J . K. and Chavepeyer, G., “Finite Amplitude Instability in the Two-Component BCnard Problem,” 32:28 I .

Schlecter. R. S., Velarde, M. G., and Platten, J. K., “Two-Component BCnard Problem,” 26:265.

Thomaes, G., “The BCnard Instabil- ity in Liquid Mixtures,” 32:269.

Weiss, N. O., “Magnetic Fields and Convection,” 32: 10 1.

.see also Dissipative structures

Berne, B. J. and Harp, G. D., “On the Calculation of Time Correlation Functions,” 17:63.

Evans, M., Evans, G., and Davies, R., “Experimental and Theoretical Studies of Rototranslational Cor- relation Functions,” 44:255.

Verdier, P. H., “Fluctuations in Autocorrelation Functions in Dif- fusing Systems,” 15: 137.

Correlation functions

Critical Phenomena Chay, T. R. and Ree, F. H., “Inequal-

ities for Critical Indices near Gas- Liquid Critical Point,” 21:43 I ,

Coopersmith, M. H., “The Thermo- dynamic Description of Phase Transitions,” 17:43.

Fixman, M., “The Critical Region,” 6:175.

Kozak, J . J., “Nonlinear Problems i n the Theory of Phase Transitions,’’ 40: 229.

SPC also Phase transitions

Tensmeyer, L. G.. Landis. P. W., and Coffey, H. F., “A Continuous Fall Method of Growing Crystals from Solution,” 21:767.

Van Hook, A., “Application of Tran- sition State Ideas to Crystal Growth Problems,” 21:7 15.

Crystal growth

Crystals Karle, J . , “The Phase Problem in

Structural Analysis,” 16: 13 I . Zandler, M. E. and Thomson, T. R..

“Application of the Significant Structure Theories to Plastic Cry- stals,” 21:5 17.

.see also Molecular solids; Solids

Deoxyribonucleic acid Douzou, P. and Sadron, C., “The

Electronic Properties of Deoxyri- bonucleic Acid,” 7:339.

Hoffmann, T. A. and Ladik. J., “Quantum Mechanical Consider- ations on Some Properties of DNA,” 7234.

Lowdin, P., “Some Aspects of the Biological Problems of Heredity, Mutations, Aging, and Tumors in View of the the Quantum Theory ofthe DNA Molecule,” 8: 177.

Pullman, B., “Steroids, Purine- Pyrimidine Pairs and Polycyclic Aromatic Carcinogens,” 8: 163.

Shimanouchi, T.. Tsuboi. M.. and Kyogoku, Y . , “Infrared Spectra of Nucleic Acids and Related Com-

ARTICLE INDEX 7

pounds,” 7:435. Wartell, R. M. and Montroll, E. W.,

“Equilibrium Denaturation of Natural and of Periodic Synthetic DNA Molecules,” 22: 129.

Detonations Cook, M. A., “Contributions of Pro-

fessor Henry Eyring to the Theory of Detonation,” 21:779.

Hirschfelder, J. 0. and Curtiss, C. F., “Propagation of Flames and Detonations,” 3:59.

Williams, F., “Electronic States of Solid Explosives and Their Proba- ble Role in Detonations,” 21:289.

Pacault, A., Hoarau, J., and Marc- hand, A., “Aspects RCcents du DiarnagnCtisme,” 3: 17 I .

Diamagnetism

Diamond Hall, H. T., “The Synthesis of Dia-

Wentorf, R. H., Jr., “Diamond Syn- mond,” 21:721.

thesis,” 9:365. Dissipative structures

Bak, T. A., “Nonlinear Problems in Thermodynamics of Irreversible Processes,” 3:33.

Ball, J. G. and Himmelblau, D. M., “The Local Potential Applied to Instability Problems,” 13:267.

Biot, M. S., “On a Unified Thermo- dynamic Approach to a Large Class of Instabilities of Dissipative Continua,” 32: 13.

Boon, J. P., “Theoretical Models for Bacterial Motion and Chemo- taxis,” 29: 169.

Clarke, B. L., “Stability of Complex Reaction Networks,” 43: 1.

Hanusse, P., Ross, J. , and Ortoleva, P., “Instability and Far-from- Equilibrium States of Chemically

Reacting Systems,” 38:3 17. Hess, B., Boiteux, A., Busse, H., and

Gerisch, G., “Spatiotemporal Organization in Chemical and Cellular Systems,” 29: 137.

Hess, B., Goldbeter, A., and Lefever, R., “Temporal, Spatial, and Func- tional Order in Regulated Bio- chemical and Cellular Systems,” 38:363.

Hurle, D. T. J. and Jakeman, E., “On the Nature of Oscillatory Convec- tion in Two-Component Fluids.” 32:277.

Kahrig, E. and Besserdich, H., “A Short Remark About Various Dis- sipative Structures,” 29: 133.

Koschmieder, E. L., “Btnard Con- vection,” 26: 177.

Koschmieder, E. L., “Stability of Supercritical BCnard Convection and Taylor Vortex Flow,” 32: 109.

Moore, D. R., “Numerical Models for Convection,” 32:65.

Morgan, J. C., “The Effect of Prandtl Number on Finite Amplitude Benard Convection,” 32:77.

Nazarea, A. D., “Electric Fields and Self-coherent Patterns and Struc- tures in Chemical Systems: Large- Scale Effects and Biological Impli- cations,” 38:4 15.

Nicolis, G., “Bifurcations and Sym- metry Breaking in Far-from-Equi- librium Systems: Toward a Dynamics of Complexity,” 55: 177.

Nicolis, G., “Dissipative Instabilities, Structure, and Evolution,” 29:29.

Nicolis, G., “Stability and Dissipa- tive Structures in Open Systems Far from Equilbrium,” 19:209.

Nicolis, G., Erneux, T., and Her- schkowitz-Kaufman, M., “Pat-


tern Formation in Reacting and Diffusing Systems,” 38:263.

Nicolis, G . , Prigogine, I., and Glansdorff, P., “On the Mecha- nism of Instabilities in Nonlinear Systems,” 32: 1.

Novak, B., “Periodical Signals in the Spatial Differentiation of Plant Cells,” 29:28 1.

Ortoleva, P. and Ross, J., “Studies in Dissipative Phenomena with Bio- logical Applications,” 29:49.

Pieranski, P. and Guyon, E., “Cylin- drical Couette Flow Instabilities in Nematic Liquid Crystals,” 32:15 1.

Platten, J. K. and Chavepeyer, G., “Finite Amplitude Instability in the Two-Component BCnard Problem,” 32:28 1.

Prigogine, I., “Quantum States and Dissipative Systems,” 15: 1 I .

Prigogine, I. and Lefever, R., “Cou- pling Between Diffusion and Chemical Reactibns,” 39: 1.

Prigogine, I. and Lefever, R., “Stabil- ity and Self-organization in Open Systems,” 29: 1 .

Richter, P. H., Procaccia, I., and Ross, J., “Chemical Instabilities,” 43:2 17.

Roberts, P. H., “Concepts in Hydro- dynamic Stability Theory,” 32: 17.

Rohde, S. M., “Some Remarks on Variational Methods, the Local Potential, and Finite Element Methods with Application to Cer- tain Continuum Mechanics Prob- lems,” 32:37.

Ross, J . and Richter, P. H., “Com- mentary: Dissipation Regulation in Oscillatory Reactions. Applica- tion to Glycolysis,” 55: 169.

Schlecter, R. S., Velarde, M. G., and

Platten, J. K., “Two-Component Benard Problem,” 26:265.

Schlogl, F., “Glansdorff-Prigogine Criterion and Statistical Theory.” 32:6 1.

Schoffeniels, E., “Commentary: A Complex Biological Oscillator,’’ 55: 17 1.

Thomaes, G., “The Benard Instabil- ity in Liquid Mixtures,” 32:269.

Thomas, D., “Diffusion-Reaction in Structured Media and Mem- branes Bearing Enzymes,” 39:229.

Thomas, D., “Functional Organiza- tion in Artificial Enzyme Mem- branes: Accomplishments and Prospects,” 29: 1 13.

Thomas, R., “Logical Description, Analysis, and Synthesis of Biologi- cal and Other Networks Compris- ing Feedback Loops,” 55247.

Turner, J. S., “Complex Periodic and Nonperiodic Behavior in the Belousov-Zhabotinski Reaction,” 55205.

Turner, J. S., “Finite Fluctuations, Nonlinear Thermodynamics, and Far-From-Equilibrium Transi- tions Between Multiple Steady States,” 29:63.

Turner, J. S., “Laboratory Experi- ments on Double-Diffusive Insta- bilities,” 32: 135.

Walter, C., “The Global Stability of Prey-Predator Systems with Sec- ond-Order Dissipation,” 29: 125.

Weiss, N. O., “Magnetic Fields and Convection,” 32: 10 I .

Wolpert, L., “The Development Pat- tern: Mechanisms Based on Posi- tional Information,” 29:253.

DNA see Deoxyribonucleic acid

ARTICLE INDEX 9

Dynamics of Life Eigen, M., “The Origin and Evolu-

tion of Life at the Molecular Level,” 55: 1 19.

Stover, B., “The Dynamics of Life. IV. Lenticular Cataracts Induced by Aging and Irradiation,” 21:66 1.

Electrochromism Labhart, H., “Electrochromism,”

13: 179. Electrode chemistry

Elving, P. J. and Pullman, B., “Mech- anisms of Organic Electrode Reactions,” 3: 1.

Tomassi, W., “Power Electrodes and Their Applications,” 3:239.

Electrolyte solutions Cernuschi, F., Giambiagi, M., and

Segre, M., “Application of a Short-Range Ordered Model to Strong Electrolytes,” 21:455.

RCsibois, P. and Hasselle-Schuer- m a n s , N . , “ M i c r o s c o p i c Approach to Equilibrium and Non-Equilibrium Properties of Electrolytes,” 11: 159.

Stecki, J., “Ionic Solvation,” 6:4 13.

Brueckner, K. A., “The Correlation Energy of a Non-Uniform Elec- tron Gas,” 14:215.

Ciiek, J . , “On the Use of the Cluster Expansion and the Technique of Diagrams in Calculations of Cor- relation Effects in Atoms and Molecules,” 14:35.

Grimaldi, F., “Correlation Effects in Diatomic Molecules Obtained

Electron correlation

from Configuration Interaction Using Hartree-Fock Orbitals. Effects on Energy and Monoelec- tronic Operators,” 14:341.

Lowdin, P., “Correlation Problem in M a n y - E l e c t r o n Q u a n t u m Mechanics. I. Review of Different Approaches and Discussion of Some Current Ideas,” 2:207.

Lowdin, P., “Some Aspects of the Correlation Problem and Possible Extensions of the Independent- Particle Method,” 14:283.

Lowdin, P., “Some Recent Develop- ments in the Quantum Theory of Many-Electron Systems and the Correlation Problem,” 8:3.

Nesbet, R. K., “Electronic Correla- tion in Atoms and Molecules,’’ 9:32 I .

Sinanoglu, O., “Electron Correlation in Atoms and Molecules,” 14:237.

Yoshizumi, H., “Correlation Prob- lem in Many-Electron Quantum Mechanics. 11. Bibliographical Survey of the Historical Develop- ments with Comments,” 2:323.

Bellemans, A. and de Leener, M., “Electron Gas in a Lattice of Posi- tive Charges,” 635 .

Brueckner, K. A., “The Correlation Energy of a Non-Uniform Elec- tron Gas,” 14:2 15.

Electron gas

Electron spectroscopy Brion, C. E. and Hamnett, A., “Con-

t i nuum Optical Oscillator- Strength Measurements by Elec- tron Spectroscopy in the Gas Phase,” 45:2.

Christophorou, L. G., Grant, M., and McCorkle, D. L., “Interactions of Slow electrons with Benzene and Benzene Derivatives.” 36:4 13.


Comer, R., “Electron Spectroscopy of Chemisorption on Metals,” 27:2 1 I .

Shirley. D. A., “ESCA,” 2335. Somorjai, G. A. and Farrell, H. H.,

“Low-Energy Electron Diffrac- tion,” 20:2 15.

Taylor, H. S., “Models, Interpreta- tions, and Calculations Concern- ing Resonant Electron Scattering P rocesses in A t o m s a n d Molecules,” 18:9 I .

Trajmar, S., Rice, J . K., and Kupper- man, A.. “Electron-Impact Spec- troscopy,” 18: 15.

Electron spin resonance Atkins, P. W. and Evans, G. T.,

“Theories of Chemically Induced Electron Spin Polarization,” 35: I .

Carrington, A., Levy, D. H., and Miller, T. A., “Electron Reso- nance of Gaseous Diatomic Molecules,” 18: 149.

Ehrenberg, A,, “Some Recent Developments in the Study of Paramagnetic Species of Biologi- cal Interest,” 7:602.

Kaufmann, K. J . and Wasielewski, M. R., “Studies of Chlorophyll in Vitro,” 47:Part 2:579.

Nicolau, C. S., “ESR Investigations on Different Plant Systems,” 7:628.

Smaller, B., “Recent Advances in EPR Spectroscopy,” 7:532.

Electronic spectroscopy Goodman, L. and Rava, R. P., “Two-

Photon Spectroscopy of Per- turbed Benzenes,” 54: 177.

Parmenter, C. S., “Radiative and Nonradiative Processes in Ben- zene,” 22:365.

Ross, I. G., “High-Resolution Elec- tronic Spectra of Large Polya-

tomic Molecules,” 20:341. Electronic structure

Ciiek, J . , “On the Use of the Cluster Expansion and the ‘Technique of Diagrams in Calculations of Cor- relation Effects in Atoms and Molecules,” 14:35.

Douzou, P. and Sadron, C.. “The Electronic Properties of Deoxyri- bonucleic Acid,” 7:339.

Drickamer, H. G. and Zahner, J . C. , “The Effect of Pressure on Elec- tronic Structure,” 4: I6 I .

Engelbrecht, L. and Hinz,e, J . . “Molecular Properties Observed and Computed,” 44: 1.


Fernandez-Alonso, .I. I., “Electronic Structures in Quantum Biochem- istry,” 7:3.

Green, S., “Sources of Error and Expected Accuracy in Ah Initio One-Electron Operator Proper- ties: The Molecular Dipole Moment,” 25: 179.

Grimaldi, F., “Correlation Effects in Diatomic Molecules Obtained from Configuration Interaction Using Hartree-Fock Orbitals. Effects on Energy and Monoelec- ironic Operators,” 14:341.

Halperin, B. I., “Properties of a Parti- cle in a One-dimensional Ran- dom Potential,” 13: 123.

Harris, F. E. and Michels, H. H.. “The Evaluation of Molecular Integrals for Slater-type Orbitals,” 13:205.

Herrick, D. R., “New Symmetry P rope r t i e s of A toms a n d Molecules,” 52: I .

Hinze, J. , “An Overview of Compu- tational Methods for Large

ARTICLE INDEX 1 1

Molecules,” 26:2 13. Hoffmann, T. A. and Ladik, J.,

“Quantum Mechanical Consider- ations on Some Properties of DNA,”7:84.

Jucys, A. P., “On the Hartree-Fock Method in Multi-Configuration Approximation,” 14: 191.

Jucys, A. P. and Kaminskas, V. A,, “On the Application of the Extended Method of Calculation to the Atomic Electrons,” 14:207.

Judd, B. R., “Effective Operators for Configurations of Equivalent Electrons,” 14:9 1.

Kelly, H. P., “Applications of Many- Body Diagram Techniques in Atomic Physics,” 14: 129.

Kiode, S. and Oguchi, T., “Theories on the Magnetic Properties of Compounds,” 5: 189.

Kotani, M., “Electronic Structure and Magnetic Properties of Hemoprote ins , Particularly Hemoglobins,” 7: 159.

KvasniEka, V., “Application of Dia- grammat ic Quasidegenerate RSPT in Quantum Molecular Physics,” 36:345.

KvasniEka, V., Laurinc, V., BiskupiE, S., and Haring, M., ”Coupled- Cluster Approach in the Elec- tronic Structure Theory of Molecules,” 52: I8 I .

Kwun, S. and Ree, T., “Ionization Potentials and Electron Affinities of Some Polyphenyl Molecules,” 21:37.

Lowdin, P., “Correlation Problem in M a n y - E l e c t r o n Q u a n t u m Mechanics. I. Review of Different Approaches and Discussion of Some Current Ideas,” 2:207.

Lowdin, P., “Some Aspects of the

Correlation Problem and Possible Extensions of the Independent- Particle Method,” 14:283.


Matsen, F. A., “Helium Molecular States,” 21: 1 .

Michels, H. H., “Electronic Excited States of Selected Atmospheric Systems,” 45:225.

Nesbet, R. K., “Atomic Bethe-Gold- stone Equations,” 14: I .

Nesbet, R. K., “Electronic Correla- tion in Atoms and Molecules,” 9:321.

Olsen, J . , Yeager, D. L., and Jsrgen- sen, P., “Optimization and Char- acterization of a Multiconfigura- tional Self-Consistent Field (MCSCF) State,” 54: 1.

Percival. 1. C., ’‘ Semiclassical Theory of Bound States,” 36: 1 .

Rajagopal, A. K., “Theory of Inho- mogeneous Electron Systems: Spin-Density-Functional Formal- ism,” 41:59.

Ramana, M. V. and Rajagopal, A. K., “Inhomogeneous Relativistic Electron Systems: A Density Functional Formalism,” 54:23 I .

Sandars, P. G. H., “A Linked Dia- gram Treatment of Configuration In t e rac t ion in Open-Shel l Atoms,” 14: 365.

Sinanoglu, O., “Electron Correlation in Atoms and Molecules,” 14:237.

Sinanoglu, 0.. “Many-Electron The- ory of Atoms, Molecules, and Their Interactions,” 6:3 15.

Tolmachev, V. V., “The Field- Theoretic Form of the Perturba- tion Theory for Many-Electron


Atoms. I . Abstract Theory,” 14:42 I .

Tolmachev, V. V., “The Field- Theoretic Form of the Perturba- tion Theory for Many-Electron Atoms. 11. Atomic Systems,” 14:47 I .

Weeks, J. D., Hazi, A., and Rice, S. A., “On the Use of Pseudopoten- tials in the Quantum Theory of Atoms and Molecules,” 16:283.

Wooley, R. G., “The Electrodynam- ics of Atoms and Molecules,” 33: 153.


Stucki, J. W., “Optimization of Mito- chondrial Energy Conversions,” 55: 141.

Energy conversion

Energy transfer Brumer, P., “Intramolecular Energy

Transfer: Theories for the Onset of Statistical Behavior,” 47:Part 1:201.

Hertel, 1. V., “Collisional Energy- Transfer Spectroscopy with Laser- Excited Atoms in Crossed Atom Beams: A New Method for Inves- tigating the Quenching of Elec- tronically Excited Atoms by Molecules,” 45341.

Hertel, 1. V., “Progress in Electronic- to-Vibrational Energy Transfer,” 50:475.

Houston, P. L., “Electronic to Vibra- tional Energy Transfer from Excited Halogen Atoms,” 47:Part 2:38 1.

McGowan, J. W., Kummler, R. H., and Gilmore, F. R., “Excitation

De-excitation Processes Relevant to the Upper Atmosphere,” 28:379.

Moore, C. B., “Vibration - Vibration Energy Transfer,” 23:4 1.

Rice, S. A,, “An Overview of the Dynamics of Intramolecular Transfer of Vibrational Energy,” 47:Part 1:117.

Rice, S . A,, “Collision Induced Intra- molecular Energy Transfer in Electronically Excited Polyatomic Molecules,” 47:Part 2:237.

Weitz, E. and Flynn, G . , “Vibra- tional Energy Flow in the Ground Electronic States of Polyatomic Molecules,” 47:Part 2: 185.

Yang, K., “The Mechanism of Elec- tronic Energy Transfer Between Excited Mercury (’Pi) Atoms and Gaseous Paraffins,” 21: 187.

see also Collisional processes; Non- radiative processes; Vibrational relaxation

Entropy Mead, C. A., “Generalizations of the

Entropy Concept: Principles, Limitations, and Prospects for Applications,” 51: 1 13.

Pfeifer, P., “A Deductive Approach to Reduced Dynamics and Entropy in Finite Quantum Sys- tems,” 53:34 1.

Enzyme kinetics Walter, C., “The Use of Product Inhi-

bition and Other Kinetic Methods in the Determination of Mecha- nisms of Enzyme Action,” 7:645.

see also Catalysis

Eigen, M., “The Origin and Evolu- tion of Life at the Molecular Level,” 55: I 19.

Margoliash, E., “The Molecular

Evolution

ARTICLE INDEX

Variations of Cytochrome c as a Function of the Evolution Spe- cies,” 29: I9 1.

Miller, S. L., “The Prebiotic Synthe- sis oforganic Molecules and Poly- mers,” 55:85.


Pngogine, I., “Nonequilibrium Ther- modynamics and Chemical Evo- lution: An Overview,” 5543.

Zander, R., “Commentary: Observa- tional Aspects Related to the Chemical Evolution of Our Atmosphere,” 5579.

Excitons Aslangul, C. and Kottis, P., “Density

Operator Description ofExcitonic Absorption and Motion in Finite Molecular Systems,” 41:32 1.

Barriol, J. and Regnier, J., “Calcula- tion of Transition Energies from the Geometry ofthe System,” 8:5.

Craig, D. P., “Model Calculations in the Theory of Mixed-Crystal Spectra,” 8:27.

Dnckamer, H. G. and Zahner, J. C., “The Effect of Pressure on Elec- tronic Structure,” 4: 16 1.

Kearns, D. R., “Electronic Conduc- tion in Organic Molecular Solids,” 7:282.

Philpott, M. R., “Some Aspects of Exciton Theory,” 23:227.

Schnepp, 0. and Jacobi, N., “The Lattice Vibrations of Molecular Solids,” 22:205.

Turlet, J. M., Kottis, Ph., and Phil- pott, M. R., “Polariton and Sur- face Exciton State Effects in the Photodynamics of Organic Molecular Crystals,” 54:303.

Explosives see Detonations

F 13

Flames Hirschfelder, J. 0. and Curtiss, C. F.,

“Propagation of Flames and Detonations,” 3:59.

Fluorescence Chance, R. R., Prock, A., and Silbey,

R., “Molecular Fluorescence and Energy Transfer Near Interfaces,” 37: 1 .

Clyne, M. A. A. and McDermid, I. S., “Laser-Induced Fluorescence: Electronically Excited States of Small Molecules,’’ 50: I .

Haas, Y . and Asscher, M., “Two- Photon Excitation as a Kinetic Tool: Application to Nitric Oxide F luorescence Quench ing ,” 47:Part 2: 17.

Krause, L., “Sensitized Fluorescence and Quenching,” 283267.

see also Electronic spectroscopy; Quenching; Radiative processes

Liehr, A. D., “Forbidden Transitions in Organic and Inorganic Sys- tems.” 5 2 4 1.

Forbidden transitions

G Glasses

Angell, C. A., Clarke, J. H. R., and Woodcock, L. V., “Interaction Potentials and Glass Formation: A Survey of Computer Experi- ments,” 48:397.

Grest, G. S. and Cohen, M. H., “Liquids, Glasses, and the Glass Transition: A Free Volume Approach , ” 48: 45 5.

Nagel, S. R., “Metallic Glasses,”


51:227. Gravel

Winterkorn, H. F., “Analogies Between Macromerit ic and Molecular Systems and the Mechanical Properties of Sand and Gravel Assemblies,” 21:75 I .

Haggerty, M. J. and Severne, G., “Kinetic Theory of Gravitational Systems,” 35: I 19.

Gravitational systems

Hydrogen bonding Eyring, E. M., Rich, L. D., McCoy, L.

L.. Graham, R. C., and Taylor, N., “Activation Parameters and Deprotonation Kinetics of Intramolecularly Hydrogen Bonded Acids,” 21:327.

Information theory Levine, R. D., “The Information

Theoretic Approach to Intramo- lecular Dynamics,” 47:Part 1 :239.

Lecomte, J., “Prospects for the Use of Infrared Spectroscopy in Biol- ogy,” 7:408.

Infrared spectroscopy

Instability Biot, M. S., “On a Unifed Thermody-

namic Approach to a Large Class of Instabilities of Dissipative Con- tinua,” 32: 13.


Pieranski, P. and Guyon, E., “Cylin- drical Couette Flow Instabilities

in Nematic Liquid Crystals,” 32: I 5 I .

Platten, J. K. and Chavepeyer, G., “Finite Amplitude Instability in the Two-Component BCnard Problem,” 32:28 I .

Richter, P. H., Procaccia, I., and Ross, J., “Chemical Instabilities.” 43:2 17.


Walgraef, D., Dewel, G., and Borck- mans, P., “Nonequilibrium Phase Transitions and Chemical Insta- bilities,” 49:3 l l .

see ulso Dissipative structures; Sta- bility

Intercalation compounds Solin, S. A., “The Nature and Struc-

tural Properties of Graphite Intcr- calation Compounds,” 49:455.

Chance, R. R., Prock, A., and Silbey, R., “Molecular Fluorescence and Energy Transfer Near Interfaces,” 37: 1.

Davis, H. T. and Scriven, L. E., “Stress and Structure in Fluid Interfaces,” 49: 35 7.

Harasima, A., “Molecular Theory of Surface Tension,” 1:203.

Jhon, M. S., Dahler, J. S., and Desai, R. C., “Theory of the Liquid- Vapor Interface,” 46:279.

Rice, S. A., Guidotti, D., Lemberg, H. L., Murphy, W. C., and Bloch, A. N., “Some Comments on the Electronic Properties of Liquid Metal Surfaces,” 27543.

Viaud, P. R., “Theoretical and Experimental Study of Stationary Profiles of a Water-Ice Mobile Solidification Interface,” 32: 163.

Vrij, A., Joosten, J. G. H., and

lnterfaces

ARTICLE INDEX 15

Fijnaut, H. M., “Light Scattering from Thin Liquid Films,’’ 48:329.

Wiegel, F. W. and Kox, A. J., “Theo- ries of Lipid Monolayers,” 41:195.

Intermolecular forces Bernstein, R. B. and Muckerman, J.

T., “Determination of Inter- molecular Forces via Low-Energy Molecular Beam Scattering,” 12:389.

Birnbaum, G., “Microwave Pressure Broadening and Its Application to Intermolecular Forces,” 12:487.

Bloom, M. and Oppenheim, I., “Intermolecular Forces Deter- mined by Nuclear Magnetic Reso- nance,” 12549.

Buckingham, A. D., “Permanent and Induced Molecular Moments and Long-Range Intermolecular Forces,” 12: 107.

Dalgarno, A., “New Methods for Cal- culating Long-Range Intermolec- ular Forces,” 12: 143.

Hirschfelder, J. 0. and Meath, W. J., “The Nature of Intermolecular Forces,” 12:3.

Kihara, T., “Intermolecular Forces and Equation of State of Gases,” 1:267.

Kihara, T., “Multipolar Interactions in Molecular Crystals,” 20: I .

Kihara, T. and Koide, A., “Inter- molecular Forces and Crystal Structures for Dz, N2, 02, Fz, and CO2,” 335 I .

Linder, B., “Reaction Field Tech- niques and Their Applications to Intermolecular Forces,” 12:225.

Mason. E. A. and Monchick, L., “Methods for the Determination of Intermolecular Forces,” 12:329.

Pitzer, K. S., “Inter- and Intramolec- ular Forces and Molecular Polari- zability,” 2:59.

Power, E. A., “Very Long-Range (Retardation Effect) Intermolecu- lar Forces,” 12: 167.

Sinanoglu, O., “Intermolecular Forces in Liquids,” 12:283.

.see also Potential energy surfaces

Gray, G. A., “Ion Cyclotron Reso- Ion-cyclotron resonance

nance,” 19: 14 1. Ion-molecule reactions

Dugan, J. V., Jr. and Magee, J. L., “Dynamics of Ion-Molecule Col- lisions,’’ 21:207.

Friedman, L. and Reuben, B. G., “A Review of Ion-Molecule Reac- tions,” 19:33.

Giese, C., ‘‘Ion-Neutral Reactions,” 10:247.

Koski, W. S., “Scattering of Positive Ions by Molecules,” 30: 185.

Isotope effects Bigeleisen, J. and Wolfsberg, M.,

“Theoretical and Experimental Aspects of Isotope Effects in Chemical Kinetics,” 1: 15.

Johnston, H. S, “Large Tunnelling Corrections in Chemical Reaction Rates,” 3: I3 1.

Kreevoy, M. M. and Konasewich, D. E., “The Br~lnsted a and the Pri- mary Hydrogen Isotope Effect. A Test of the Marcus Theory,” 21:243.

Kinetic theory see Statistical mechanics of irreversi-

ble processes


Kinetics .SLY Chemical dynamics

Laser induced fluorescence sec. Fluorescence; Radiative pro-

cesses Lasers

Ben-Shaul, A., “Chemical Laser Kinetics,” 47:Part 2:55.

Bullis, R. H., “Applications to Lasers,” 28:423.

Cantrell, C. D., Makarov, A. A,, and Louisell, W. H., “Laser Excitation of SF6: Spectroscopy and Coher- ent Pulse Propagation Effects,” 47:Part 1:583.

Dion, D. R. and Hirschfelder, J. O., “Time-Dependent Perturbation of a Two-State Quantum System by a Sinusoidal Field,” 35265.

Fleming, G. R., “Applications of Continuously Operating, Syn- c h r o n o u s l y M o d e - L o c k e d Lasers,” 49: I .

Light scattering Birnbaum, G., Guillot, B., and Bra-

tos, s., “Theory of Collision - Induced Line Shapes-Absorp- tion and Light Scattering at Low Density,” 51:49.

Boon, J. P., “Light Scattering from Nonequilibrium Fluid Systems,” 32:87.

Fleury, P. A. and Boon, J. P., “Laser Light Scattering in Fluid Sys- tems,” 24: I .

Frommhold, L., “Collision-Induced Scattering of Light and the Dia- tom Polarizabilities,” 46: l .

Gelbart, W. M., “Depolarized Light

Scattering by Simple Fluids,” 26: I .

Vrij, A., Joosten, J. G. H., and Fijnaut, H. M., “Light Scattering from Thin Liquid Films,” 48:329.

B e n - R e u v e n , A. , “ S p e c t r a l Lineshapes in Gases in the Binary- Collision Approximat ion ,” 33:235.

Ben-Reuven, A. and Rabin, Y., “ N - Level Multiple Resonance,” 47:Part 1 5 5 5 .

Birnbaum, G., “Microwave Pressure Broadening and Its Application to Intermolecular Forces,” 12:487.

Birnbaum, G., Guillot, B., and Bra- tos, s., “Theory of Collision - Induced Line Shapes-Absorp- tion and Light Scattering at Low Density,” 51:49.

Greer, W. L. and Rice, S. A,, “On the Theory of Optical Absorption Profiles in Condensed Systems,” 17:229.

Kubo, R., “A Stochastic Theory of Line Shape.” 15: 10 I .

McGurk, J. C., Schmalz, T. G., and Flygare, W. H. , “A Density Matrix, Bloch Equation Descrip- tion of Infrared and Microwave Transient Phenomena,” 25: I .

Morrey, J. R. and Morgan, L. G., “T, Frequency Functions as Energy Contours for Photon Absorbance in Condensed Systems,” 21:3 17.

Forster, D., “The Theory of Liquid Crystals,” 31:23 I .

Pieranski, P. and Guyon, E., “Cylin- drical Couette Flow Instabilities in Nematic Liquid Crystals,” 32:151.

Tobolsky, A. V. and Samulski, E. T.,

Line shapes

Liquid crystals

ARTICLE INDEX 17

“Solid ‘Liquid-Crystalline’ Films of Synthetic Polypeptides: A New State of Matter,” 21:529.

Liquid metals Ballentine, L. E., “Theory of Elec-

tron States in Liquid Metals,” 31:263.

Bellemans, A. and de Leener, M., “Electron Gas in a Lattice of Posi- tive Charges,” 6:85.

McLachlan, D., Jr., ‘‘ The Gaseous Fraction in Liquid Metals,” 21:499.

Nachtrieb, N. H., “Solutions of Metals in Molten Salts,” 31:465.

Oriani, R. A. “Thermodynamics of Metallic Solutions,” 2: 1 19.

Rice, S. A., Guidotti, D., Lemberg, H. L., Murphy, W. C., and Bloch, A. N., “Some Comments on the Electronic Properties of Liquid Metal Surfaces,” 27:543.

Liquids Adelman, S. A. and Deutch, J. M.,

“The Structure of Polar Fluids,” 31:103.

Andersen, H. C., Chandler, D., and Weeks, J. D., “Role of Repulsive and Attractive Forces in Liquids: The Equilibrium Theory of Clas- sical Fluids,” 34: 105.

Blum, L. and Narten, A. H., “Dif- fraction by Molecular Liquids,” 34:203.

Boon, J. P., “Light Scattering from Nonequilibrium Fluid Systems,” 32:87.

Dahler, J . S. and Theodosopulu, M., “The Kinetic Theory of Dense Polyatomic Fluids,” 31: 155.

Davis, H. T., “Kinetic Theory of Dense Fluids and Liquids Revis- ited,” 24:257.

Desai, R. C. and Yip, S., “A Stochas-

tic Model for Neutron Scattering by Simple Liquids,” 15: 129.

Egelstaff, P. A., “New Experimental Studies of the Structure of Fluids,” 53: 1.

Fleury, P. A. and Boon, J. P., “Laser Light Scattering in Fluid Sys- tems,” 24: I .

Frisch, H. L., “The Equation of State of the Classical Hard Sphere Fluid,” 6:229.

Gelbart. W. M., “Depolarized Light Scattering by Simple Fluids,” 26: 1 .

Jhon, M. S., “Sound Velocity and van der Waals Force in Liquids According to Significant Structure Theory,” 21:48 I .

Karnicky, J. F. and Pings, C. J., “Recent Advances in the Study of Liquids by X-ray Diffraction.” 34: 157.

Lee, Y., Ree, F. H., and Ree, T., “Distribution Function of Classi- cal Fluids of Hard Spheres. I,” 21:393.

Luks, K. D. and Kozak, J. J., “The Statistical Mechanics of Square- Well Fluids,” 37: 139.

Pak, H. and Chang, S., “Transient State Theory of Significant Liquid Structure Applied to Water,” 21:487.

Prigogine, I., Nicolis, G., Allen, P. M., “Eyring’s Theory of Viscosity of Dense Media and Nonequili- brium Statistical Mechanics,” 21:473.

Reiss, H., “Scaled Particle Methods in the Statistical Thermodynam- ics of Fluids,” 9: 1.

Schwarz, K. W., “Mobilities of Charge Carriers in Superfluid Helium,” 33: 1.


Stillinger, F. H., “Theory and Molec- ular Models for Water,” 31: I .

Utsugi, H. and Ree, T., “Application of the Absolute Reaction-Rate Theory t o Non-Newtonian Flow,” 21:273.

Watts, R. O., Henderson, D., and Baxter, R. J . , “Hard Spheres with Surface Adhesion: The Percus- Yevick Approximation and the Energy Equation,” 2142 1.

M Macromolecules

see Polymers Magnetic circular dichroism

Stephens, P. J . , “Magnetic Circular Dichroism,” 35: 197.

Magnetic properties Ehrenberg, A,, “Some Recent

Developments in the Study of Paramagnetic Species of Biologi- cal Interest,” 7:602.

Erber. T., Latal, H. G., and Harmon, B. N., “The Origin ofHysteresis in Simple Magnetic Systems,” 20:7 I .

Kiode, S. and Oguchi, T., “Theories on the Magnetic Properties of Compounds,” 5: 189.

Kotani, M., “Electronic Structure and Magnetic Properties of Hemoprote ins , Particularly Hemoglobins,” 7: 159.

Philippot, J. , “Nuclear Paramagnetic Relaxation in Solids,” 11:289.

Schoffa, G., “Magnetic Susceptibili- ties and the Chemical Bond in Hemoproteins,” 7: 182.

Stephens, P. J . , “Magnetic Circular Dichroism,” 35: 197.

Weiss, N. O., “Magnetic Fields and Convection,” 32: 101.

Many-body problem Adelman, S. A., “Generalized

Langevin Equations and Many- body Problems in Chemical Dynamics,” 44: 143.

Kelly, H. P., “Applications of Many- Body Diagram Techniques in Atomic Physics,” 14: 129.

Lowdin, P., “Correlation Problem in M a n y - E l e c t r o n Q u a n t u m Mechanics. 1. Review of Different Approaches and Discussion of Some Current Ideas,” 2:207.


Sinanoglu, O., “Many-Electron The- ory of Atoms, Molecules, and Their Interactions,” 6:3 15.

Tolmachev, V. V., “The Field- Theoretic Form of the Perturba- tion Theory for Many-Electron Atoms. I . Abstract Theory,” 14:42 1.

Tolmachev, V. V., “The Field- Theoretic Form of the Perturba- tion Theory for Many-Electron Atoms. 11. Atomic Systems.” 14:47 1.


see also Chemical dynamics

Kosloff, R., “Thermodynamic Aspects of the Quantum-Mechan- ical Measurement Process,” 46: 153.

Primas, H. and Miiller-Herold, U.,

Measurement theory

ARTICLE INDEX 19

“Quantum-Mechanical System Theory: A Unifying Framework for Observations and Stochastic Processes in Quantum Mechan- ics,” 38: I .

Membranes Bolis, L., “Structure and Transport

in Biomembranes,” 29:30 1. Chen Y., “Noise Analysis of Kinetic

Systems and Its Applications to Membrane Channels,” 37:67.

Clayton, R. K., “Photochemical Reaction Centers and Photosyn- t hetic Membranes,” 19: 3 5 3.

de Levie, R., “Mathematical Model- ing of Transport of Lipid-Soluble Ions and Ion-Canier Complexes Through Lipid Bilayer Mem- branes,” 37:99.

Delmotte, M., Julien, J . , Charle- magne, J., and Chanu, J., ”Ther- modynamic Considerations ofthe Excitable Membranes Behavior,” 29:343.

Goodwin, B. C. , “A Membrane Model for Polar Transport and Gradient Formation,” 29:269.

Kobatake, Y., “Physiochemical Problems in Excitable Mem- branes,” 29:3 19.

Lauger, P., “Ion Transport Through Artificial Lipid Membranes,” 29:309.

Lefever, R. and Deneubourg, J. L.. “Membrane Excitation,” 29:349.

McConnell, H., “Dynamic Proper- ties of Membranes: Membrane Immunochemistry,” 39:275.

Monnier, A. M., “Excitability and Ionic Selectivity, Common Prop- erties of Many Lipidic Deriva- tives,” 29:34 1.

Simon, W., “Selective Transport Processes in Artificial Mem-

branes,” 39:287. Thomas, D., “Diffusion-Reaction in

Structured Media and Mem- branes Bearing Enzymes ,” 39:229.

Thomas, D., “Functional Organiza- tion in Artificial Enzyme Mem- branes: Accomplishments and Prospects,” 29: 1 13.

Woodbury, J. W., “Eyring Rate The- ory Model of the Current-Voltage Relationships of Ion Channels in Excitable Membranes,” 21:601.

Bearman, R. J., Kirkwood, J. G., and Fixman, M., ”Statistical-Mechan- ical Theory of Transport Pro- cesses. X. The Heat of Transport in Binary Liquid Solutions,” 1 : l .

Bellemans, A., Mathot, V., and Simon, M., “Statistical Mechanics of Mixtures-The Average Poten- tial Model,” 1 I : 1 17.

Blander, M., “Dimensional Methods in the Statistical Mechanics of Ionic Systems,” 11:83.

Burton, L. L. and Van Artsdalen, E. R., “On the Nature ofSolutions of Organic Compounds in Fused Salts,” 21:523.

Hijmans, J. and Holleman. Th., “l’he Principle of Corresponding States for Chain-molecule Liquids and their Mixtures,” 16:223.

Lamm, O., “Studies in the Kinemat- ics of Isothermal Diffusion. A Macrodynamical Theory of Mul- ticomponent Fluid Diffusion.” 6:295.

Nachtrieb, N. H., “Solutions of Metals in Molten Salts,” 31:465.

Oriani, R. A. “Thermodynamics of Metallic Solutions,” 2: I 19.

Rowlinson, J. S. and Richardson, M.

Mixtures


J., “The Solubility of Solids in Compressed Gases,” 295.

Schneider, G. M., “Phase Equilibria in Fluid Mixtures at High Pres- sures,” 17: 1 .


van der Waals, J. H. and Platteeuw, J. C., “Clathrate Solutions,” 2: I .

see also Solutions

Andersen, J. B., Andres, R. P., and Fenn, J. B., “Supersonic Nozzle Beams,” 10: 27 5.

Bederson, B. and Robinson, E. J., “Beam Measurements of Atomic Polarizabilities,” 10: 1.

Bernstein, R. B. and Muckerman, J. T., “Determination of Inter- molecular Forces via Low-Energy Molecular Beam Scattering,” 12:389.

Bersohn, R. and Lin, S. H., “Orienta- tion of Targets by Beam Excita- tion,” 16:67.

Eschenroeder, A. Q., “Reaction Kinetics in Hypersonic Flows,” 13: 19.

Haberland, H., Lee, Y. T., and Siska, P. E., “Scattering of Noble-Gas Metastable Atoms in Molecular Beams,” 45487.

Herschbach, D., “Reactive Scattering in Molecular Beams,” 10:319.

Lawley, K. P., “New Directions in Molecular Beams,” 30: 1.

Ng, C. Y., “Molecular Beam Pho- toionization Studies of Molecules and Clusters,” 52:263.

Rice, S. A., “Collision Induced Intra- molecular Energy Transfer in Electronically Excited Polyatomic Molecules,” 47:Part 2:237.

Molecular beams

Molecular solids Duchesne, J., “Nuclear Quadrupole

Resonance in Irradiated Cry- stals,’’ 2: 187.

Kearns, D. R., “Electronic Conduc- tion in Organic Molecular Solids,” 7:282.

Meyer, L., “Phase Transitions in van der Waal’s Lattices,” 16:343.

Schnepp, 0. and Jacobi, N., “The Lattice Vibrations of Molecular Solids,” 22:205.

see also Excitons; Solids

Bastiansen, 0. and Skancke, P. N.. “Electron Diffraction in Gases and Molecular Structure,” 3:323.

Brown, J. M. and Jmgensen, F., “Vibronic Energy Levels of a Lin- ear Triatomic Molecule in a Degenerate Electronic State: A Unified Tratment of the Renner- Teller Effect,” 52: I 17.

Browne, J. C. and Matsen, F. A., “ A b Initio Calculations on Small Molecules,” 23: 16 1 .

Burdett, J. K., “Predictions of the Structure of Complex Solids,” 49:47.

Carlson, C. M., “A Linear Sum-over- Points Approach for Computing Electronic Energies: Application to He and H2 Using Conroy Diophantine Points,” 21:49.

Lathouwers, L. and Van Leuven, P., “Generator Coordinate Theory of Nuclear Motion in Molecules,” 49: I 15.

Somorjai, G. A. and Farrell, H. H., “Low-Energy Electron Diffrac- tion,” 20:2 15.

Wilson, E. B., Jr., “The Problem of Bamers to Internal Rotation in Molecules,” 2:367.

Molecular structure

Documents

Advances CHEMICAL PHYSICS - download.e-bookshelf.de fileEDITORIAL BOARD C. J. BALLHUSEN, Kobenhaven Universitets Fysisk-Kemiske Institut. Kemisk BRUCE BERNE, Depatment of Chemistry,