REGNIRPS STCART NI NREDOM SCISYHP Ergebnisse der exakten Natur- wissenschaften 37 Volume Editor: G.H6hler Associate Editor: E.A. Niekisch Editorial Board: .S Flegge .J Hamilton .F Hund .H Lehmann .G Leibfried W.Paul Springer-Verlag Berlin Heidelberg New York 5791 Manuscripts for publication should eb addressed to: G. HOHLER, Institut fiir Theoretische Kernphygik der Universit~t, 75 Karlsruhe ,1 Postfach 6380 Proofs and all correspondence concerning papers in ehl process of publication should eb addressed to: E. A. NIEKISCH, Institut fiir GrenzflXchenforschung und Vakuumphysik der Kern- Iorschungsanlage Jiilich, 517 J tilich, Postfach 365 ISBN 3-540-06943-7 Springer-Verlag Berlin Heidelberg New York ISBN 0-387-06943-7 Springer-Verlag New York Heidelberg Berlin This work is subject to copyright. All rights are reserved, whether the whole or part of the material is con- cerned, specifically those of translation reprinting re-use of illustrations, broadcastmg, reproduction by photocopying machine or similar means, and storage in data banks. Under 54 § of the German Copyright Law where copies are made for other than private use, a fee is payable to the publisher, the amount of the fee to be determined by agreement with the publisher. © by Sprmger- Verlag~ Berlin • Heidelberg 1975. Library of Congress Cataloging in Publication Data. Haken, H. : Excitons at high density. (Springer tracts irt modern physics; v. 73) Bibliography: p. Includes index. .1 Exciton theory. I. Nikitine, Serge, joint author. II. Bagaev, V. S. III. Title. IV. Series. QCL. $797 vol. 73 [QC176.8.E9] 539'. 08s [530.4'1] 74-22397 The use of general descriptive names, trade names, trade marks, etc. in this publication, even ff the former are not especiaUy identified,i s not be taken as a sign that such names, as understood by the Trade Marks and Merchandise Marks Act, may accordingly be used freely by anyone. Typesetting, printing and bookbinding: Brtihlsche Uuiversit~tsdruckerei, GieBen Excitons at High Density Edited by H. NEKAH and .S ENITIKIN stnetnoC I. Introduction Survey. H. NEKAH and .S NIKmNE . . . . . . . . . . . . . . 2 Introduction to Exciton Spectroscopy. .S ENITIK1N ....... 5 II. Biexcitons Properties of Biexcitons. S. NIKmNE . . . . . . . . . . . . . 81 Biexcitons- Bose Condensation and Optical Response. E. HAN~ 34 HI. Electron-Hole Droplets Properties of Electron-Hole Drops in Germanium Crystals. V. .S V~O~GAB . . . . . . . . . . . . . . . . . . . . . . . 27 Theory of Electron-Hole Drops in Germanium and Silicon. T. M. RICE . . . . . . . . . . . . . . . . . . . . . . . . 19 IV. Biexcitons and Droplets Spectroscopic Study of Exciton-Exciton Interaction (Biexcitons, Drops) in Semiconducting Crystals. .B V. VOKIVON ...... 601 Exciton Condensation in Germanium. A. A. VEHChGOR ..... 721 V. Special Optical Properties of Excitons at High Density Gigantic Oscillator Strength Inherent in Exciton Complexes. E. I. ABHSAR . . . . . . . . . . . . . . . . . . . . . . . 051 Interaction between Excitons at High Concentration. R. ,YVEL A. ,SAVIB J. B. ,NURG and .S NmmNE . . . . . . . . . . . . 171 VI. Laser Action of Excitons Theory of Stimulated Emission by Excitons. H. NEKAH and S. ENITIKIN . . . . . . . . . . . . . . . . . . . . . . . . 291 Experimental Investigation on the Competition of Stimulated Emissions Involving Excitons. R. ,YVEL J. B. ,NURG and .S Nn<mNE 112 Experimental Studies of Excitons at High Densities. K. L. EELKAHS 221 IV stnetnoC VII. Excitonic Polaritons at Higher Densities Tests of Validity of Spatial Dispersion Theories on Lead Iodide Crystals Spectra. M. ,NNAMSORG J. ,NNAMLLEIB and S. NIKITINE 242 Medium and High Polariton Densities. H. MAHR . . . . . . . . 265 Polaritons at High Intensities and in Bose Condensed Exciton Systems. H. HAKEN, J. GOLL, and A. SCHENZLE 285 . . . . . . . . Subjeet Index .... . . . . . . . . . . . . . . . . . . . 297 Classified Index of Authors and Titles . . . . . . . . . . . . . 299 yevruS H. NEKAH and .S ENITIKIN Excitons at high density and polaritons offer a new field of research within the framework of semiconductor physics. The pioneering work of Nikitine, Gross and others has established that hydrogen-like excitons may be created in semiconductors. These excitons are made up of an electron of the conduction band and a hole of the valence band, usually described by effective masses, which are coupled together by the Coulomb interaction, possibly modified by polarization effects. At this stage a great variety of Rydberg constants and further generalizations beyond the hydrogen atom are found, because both the effective masses and the effective Coulomb interaction depend on the different crystals involved. Furthermore, in certain crystals tensor masses must be taken into ac- count, and excitons may belong to different valleys of the conduction and valence band. Finally, the effective moments of the electron and the hole may differ from that of free electrons. Detailed investigations of the different bound states of excitons are still in progress, but a new field has recently emerged thanks to the possibility of creating high concentrations of excitons. The usual way of producing such high concentrations is by shining laser light on the insulating crystals. In large classes of crystals excitons may form ex- citonic molecules ("biexcitons") in analogy to the hydrogen molecule. On the other hand, the effective interaction between excitons may also be repulsive, hence bose condensation of excitons may be possible. Bose condensation of biexcitons has also been considered and there are some experimental indications that such an effect exists. Another field currently eliciting great interest si the formation of electron-hole droplets. Here the excitonic binding has broken up and some sort of metallic drop has been formed, bound together mainly by the Coulomb exchange interaction between the electrons and holes. A further possibility that has been discussed is the formation of poly- excitons. It is even suggested that excitons may form a crystal, pre- sumably of the type of a quantum crystal, within the crystal. Thus -xe citons would form a new type of matter within matter. We are convinced that the various possibilities are by no means exhausted, because the mass ratio between the exciton and hole may vary over a wide range. yevruS 3 Many of the properties of excitons are investigated by optical means, so that the detailed study of the interactions between light and excitons at high intensity is of great importance. We have therefore included in this volume several articles dealing with the polariton concept. Polaritons consist of an exciton and a photon. At high concentrations of excitons or polaritons new effects of light propagation appear. Thus, one might expect the dispersion curve of the polariton to be changed and perhaps even to find self-induced transparency of excitons. Moreover, inter- actions between polaritons can give rise to a number of different scat- tering processes. Excitons at high density may also produce stimulated emission of light; this process is of great practical interest because of the extremely high gain of such lasers. The present authors think that this field is worthy of particularly intensive development because many different processes may be competing with each other, and both temporal and spatial transient states may play an important role. It is hoped that the present book will stimulate further research work in this extremely fascinating field. The articles in this book (except those by Novikov and Rashba) were presented at an international symposium at Tonbach, Germany. We wish to thank the Deutsche Forschungsgemeinschaft and the Land Baden-Wtlrttemberg for financial support and Mrs. Funke for her efficiency in organizing this meeting. Introduction to Exciton Spectroscopy* S. NIKITINE Contents .1 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 .2 Early Observations . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 .3 Classification of Exciton Transitions . . . . . . . . . . . . . . . . . . . . 6 a) First-Class Spectra . . . . . . . . . . . . . . . . . . . . . . . . . . 7 b) Second-Class Transitions . . . . . . . . . . . . . . . . . . . . . . . 8 )c Indirect Transitions . . . . . . . . . . . . . . . . . . . . . . . . . . 9 d) High-Energy Spectra . . . . . . . . . . . . . . . . . . . . . . . . . 9 .4 The Spectrum of Cu20 . . . . . . . . . . . . . . . . . . . . . . . . . 9 .5 Solid-State Spectroscopy and Band Structure ................ 21 Recent Developments . . . . . . . . . . . . . . . . . . . . . . . . . . . 41 References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 51 1. Introduction This short paper should not be considered as a review of exciton spec- troscopy but only as an introduction. For detailed information, the reader should consult review papers -1-4. Some of these papers are, however, rather out-of-date. Exciton spectroscopy has developed very rapidly and, to the author's knowledge, no attempt has been made to summarize its present state. This introduction is not intended to fill this gap but to facilitate the approach to the reports that follow. It is limited to classic results: It is hoped that the non-specialist reader will find these remarks helpful. 2. Early Observations Though some work was carried out on solid-state spectroscopy in the early twenties 5, 6, modern work was started some 22 years ago by Hayashi Mazakuzu 7, by Gross 8 and his group, and by the Stras- bourg group 9. Other groups joined this research later 10. ; This work was carried out within the frame of the agreement on French-German scientific cooperation between C.N.R.S., Paris, Universit6 Louis Pasteur, Strasbourg, and Universitiit Stuttgart. 6 S. Nikitine Semiconductors and insulating crystals, ionic or covalent, exhibit two types of spectra in the low-energy absorption edge: a) This edge may exhibit one or several sharp absorption peaks. In some cases, they form series converging to a continuum. The series are sometimes hydrogen-like. The peaks have been shown to be due to the optical formation of excitons, an excited state of the crystal in which an electron and a hole are bound in a state resembling that of the hydrogen atom. b) The edge may exhibit absorption steps. These steps have been recognized to be due to band-to-band transitions or to transitions to exciton states with the cooperation of phonons. They are known as indirect transitions. The formation of excitons is essential for an understanding of this part of the spectrum. In high-energy absorption rather broad peaks are also observed. They might be ascribed to exciton transitions of higher energies, or to band-to-band transitions at points in the Brillouin zone where the joint density of states has a pronounced maximum. Equidistant peaks apparently forming vibrational satellites of exciton peaks have been reported 11. The separation of these peaks agrees well with the LO phonon of the crystal. It has been shown by the Strasbourg group that the reflection spectra sometimes exhibit drastic anomalies 12. Most of these anomalies cor- respond to the first and second exciton peaks of a series. Some exciton spectra are, however, weak and do not give rise to anomalies. The anoma- lies consist of a pronounced maximum and a sharp minimum of reflection, called excitonic residual ray and missing ray, respectively. Maxima of reflection can also be observed in the high-energy spectrum and can be ascribed to high-energy exciton transitions or to transitions at par- ticular points in the Brillouin zone. Some weak lines on the low-energy side of exciton peaks depend on the quality of the crystal and have been named "sensitive lines" by the Strasbourg group 13. They have been ascribed to complexes formed by excitons captured by defects or impurities. Exciton luminescence was first observed by Grillot 14 independ- ently by the Strasbourg group -15, and by Archangelskaja et al. 16. This luminescence exhibits narrow and broad lines and sometimes vibrational satellites. 3. Classification of Exciton Transitions These observations have stimulated theoretical work and it has been shown by Elliott 17 and Haken 18 that several classes of exciton spectra can be described by the theory 3. Introduction to Exciton Spectroscopy 7 a) First-Class Spectra This class corresponds to transitions according to the selection rules k = 0, A k = 0, where k is the wave vector of excitons. In this class ex- citons in a spectroscopic S state are formed. A series of lines is expected: v = o~v - R~x/n 2 with n=1,2,3.., xeR is an excitonic Rydberg constant, xeR = (R/e z) (#/mo), where e is a dielectric constant, 0m the mass of the electron in the vacuum at rest, # the effective mass of the exciton, and R the atomic Rydberg constant. Haken's correction 18 has to be used for the calculation of .5 The oscillator strength per unit cell is of the form f = const/e 3 n 3 and typical values are about 10-2 to 01 -3. For v > ~ov the theory predicts a continuous absorption, which corresponds to a band-to-band tran- sition taking into account electron-hole interaction. Some observed spectra are tentatively ascribed to this class. Though the quantitative agreement is in many cases not very good, the quali- tative description and the orders of magnitude are well predicted by the theory. It has to be remembered that the theory is based on assumptions that are only roughly realistic in many cases. CuI, CuC1 and CuBr are quoted as examples of such transitions 19; one of these spectra is shown in Fig. .1 Only this class of spectra shows excitonic residual rays 12: Fig. 2 shows one of the residual rays reported by the Stras- bourg group 20. c. 31 d:l & t. t- "O o ,. 3550 36'00 36'50 37'00 37.50 38'00 3850 %(A~ Fig. .1 Spectrum of CuC1 (thin film) at 4.2 K showing a number of peaks. The spectrum is ascribed to the first-class type of exciton transition. The spectrum has a somewhat com- plicated character on account of the overlap of two series (the sharp and diffuse series) separated by the spin-orbit splitting of the valence band.Vibrational satellites can be seen on the high-energy side 8 S. Nikitine %(R 100 80 O6 4O 20" (~,1 x a6oo 0 ' 3700 ' 38'00 ' a9bo , 4obo Fig. .2 Reflection spectrum of CuC1 at 4.2 K showing strong anomalies, excitonic residual rays and missing rays for the first line of both series b) Second-Class Transitions Elliott -17 has shown that, when the matrix element of the transition moment is zero on account of the valence-band (V.B.) and the con- duction-band (C.B.) wave functions having the same parity at the F point, another class of transitions is possible in the electric dipole ap- proximation. The selection rules are A k = 0, and k + 0 but small. In this case excitons in a spectroscopic P state are created. The series of lines is still given by v = v~ - Rex/n 2 but n = 2, 3, 4 .... The transition to the n = 1 state is forbidden in the dipole approximation but can take place in the quadrupole or magnetic dipole approximations. The oscillator strength is f = const (n z - 1)/~32 n s . Again Haken's corrections must be used for .e f is of the order of mag- gnitude of 10-6 For the quadrupole transition the order of magnitude is of about 10-9 For v > oov the absorption is again a continuum. First- and second-class transitions are not expected to be possible for the same transition unless the crystal has no center of symmetry. It has been shown by the Strasbourg group that the yellow and green series of Cu20 are well described by the theory of second-class transi- tions. Indications in favor of such transitions have been reported for SnO2, but transitions of this class are exceptional 211.