SEMICONDUCTING 11-VI, IV-VI, V-VI anct COMPOUNDS MONOGRAPHS IN SEMICONDUCTOR PHYSICS Valurne 1: Heavily Doped Semiconductors by Viktar I. Fistul' Valurne2: Liquid Semiconductors by V. M. Glazav, S. N. Chizhevskaya, and N. N. Glagaleva Valurne 3: Semiconducting II-VI, IV-VI, and V-VI Compounds by N. Kh. Abrikasav, V. F. Bankina, L. V. Paretskaya, L. E. Shelirnava, and E. V. Skudnav.a In preparation: Switching in Semiconductor Diodes by Yu. R. Nasav SEMICONDUCTING 11-VI, IV-VI, V-VI anct COMPOUNDS N. Kh. Abrikosov, V. F. Bankina, L. V. Poretskaya, L. E. Shelimova, and E. V. Skudnova A. A. Baikov Institute of Metallurgy Academy of Seiences of the USSR Translated from Russian by Albin Tybulewicz Editor, Soviet Physics-Semiconductors ~ Springer Science+B usiness Media, LLC 1969 Professor Nikolai Khrisanfovich Abrikosov, who is Director of Laboratories at the A. A. Baikov Institute of Metallurgy, has been engaged in research on rare earth meta! alloys since 1936 and work on semiconducting materials since 1950. He is a member of the Scientific Council on the Chemistry and Tcchnology of Semiconductors of the Academy of Seiences of the USSR, as weil as a member of the scientific boards of the A. A. Baikov Institute of Metallurgy, the N. S. Kurnakov Institute of General and Inorganic Chemistry, the State Scientific Research Institute for Rare and Less Common Metals, and the Moscow Institute for Steel and Alloys. Library of Congress Catalog Card Number 69-12527 The original Russian text, published by Nauka Press in Moscow in 1967, has been corrected and updated by the authors for the present edition. A6punoroiJ H. X., Banl>Uita B. fP., /Iope!fna,q, JJ. B., meAU.ltOIJa JJ. E. CnyonoBaE. B. 0 lloJiynpoBO,[J;HHROBhie coep;HHeHHH, HX noJI~eHHe n: CBOMCTBa POLUPROVODNIKOVYE SOEDINENIYA, IKH POLUCHENIE I SVOISTA © 1969 Springer Science+ Business MediaNe w York Originally published by Plenum Press in 1969 Softcover reprint of the hardcover 1st edition 1969 All rights reserved No part of this publication may be reproduced in any form without written permission from the publisher. ISBN 978-1-4899-6185-3 ISBN 978-1-4899-6373-4 (eBook) DOI 10.1007/978-1-4899-6373-4 PREFACE This monograph deals with the semiconducting compounds formed from elements of groups II, IV, or V and sulfur, selenium, or tellurium. These compounds are attracting increasing atten tion because they have interesting physical properties. The mono graph describes the crystal structures of these compounds, and presents the published data on their polymorphic transitions, in cluding transitions observed at high pressures. The problems of chemical binding are discussed. In the sections dealing with the phase diagrams, special at tention is paid to the departures of semiconducting compounds from stoichiometry and investigation methods are described for the precise determination of the composition of these compounds. Analysis of the published material has shown that the character istic feature of semiconducting compounds with a predominantly covalent type of chemical binding is a departure from stoichiom etry. This departure is sometimes very small, representing hundredths and thousandths of 1%, but it strongly affects the physi cal properties of these compounds. The composition of these compounds does not remain con stant, but is affected by external conditions: temperature, pres sure, and the concentration of the third component. Because of this, the phase diagrams of the "temperature-composition" type are insufficient for many of these systems. It is also necessary to know the equilibrium phase diagrams of the "pressure-tempera ture-composition" (P-T-X) type. Knowledge of the P-T-X dia grams is particularly important in the synthesis of semiconduct ing compounds having high vapor pressures. The monograph in cludes all the published P-·T-X diagrams for the compounds dis cussed and describes a method for plotting these diagrams. Inves- V vi PREFACE tigations of the P-T-X diagrams of semiconducting compounds are of relatively recent origin and it is hoped that the review of these investigations will attract more attention of research workers to such diagrams. The more important physicochemical proper ties of the compounds are also given in the monograph. Unfortu nately, the published material is insufficient for a full description of the thermodynamic properties of many of the compounds con sidered. More work should be done on these properlies. The main physical properties of the compounds are given: the forbidden band width, the carrier mobility, the effective masses of carriers, the electrical conductivity, and the thermo electric power. The monograph consists of three chapters. The first deals with chalcogenides of elements in group II: zinc, cadmium, and mercury. The second discusses semiconducting compounds of elements in group IV: germanium, tin, and lead. These com pounds are used in some photoelectric and thermoelectric devices. And the third describes investigations of compounds of elements of group V: arsenic, antimony, and bismuth. Allthese chalcogenides, as well as solid solutions based on them, are of great importance because of their application as thermoelectric materials in low temperature thermoelectric converters and cooling devices. The monograph does not cover chalcogenides of elements in group III (aluminum, gallium, and indium), since a book by Z. S. Medvedeva dealing with these compounds is being published simul taneously with the present monograph. We have also excluded the data on semiconducting glasses because these materials deserve a separate book. The monograph includes the published data (right up to the second half of 1966) on the crystal structure, physicochemical properties, and phase diagrams of important semiconducting com pounds which are used in various bl'anches of engineering. Some of these compounds have been investigated by the authors of the present monograph. The authors will be grateful for any comments from readers. N. Kh. Abrikosov CONTENTS CHAPTER I. AllE VI Compounds § 1. C rystal structure. • • • • • • • • , • • • • • • • . • . 1 § 2. Crystallographic Polarity . • • • . • . • • . • • • • 6 § 3. Chemical Binding of All B VI Compounds • • • • • 8 §4. Phase Diagrams of All-E VI Binary Systems • 11 § 5. Thermodynamic Properties • • • • • • • • • • • • • 23 § 6. Physical Properties • • • • • • • . • • • • • . • . • • 26 § 7. Preparation Methods • • • • • • • • . . • • . • • • • 33 § 8. Systems Based on AllE VI Compounds • • • • • • 43 Literature Cited. • • • • • . • • • . • • • • • • • • • • • • • 59 CHAPTER ll. AJVB VI Compounds § 1. Phase Diagrams of Al V-B VI Binary Systems • 65 §2. Crystal structure and Chemical Binding..... 74 §3. Departures from Stoichiometry • • • • . . • • • • 82 §4. Properties of AIVB VI Compounds ••••••• , • 103 § 5. Preparation Methods • • • • • • • • • • • • • . • • • 116 §6. Chalc~enides of AIVBi'!, A~VB{'I, and AlVB4 Type. • • • • • • • • • • • • • • • . • • . • • • 122 § 7. Systems Based on AlVB VI Compounds. . • . • • 127 Literature Cited. • • • • . . . • • • . . . • • • • • • • • • • 151 CHAPTER III. AYBi'l Compounds § 1. Phase Diagrams of A V-B VI Binary Systems • 159 § 2. Crystal Structure and Chemical Binding. • . . • 175 §3. Departures from Stoichiometry of Compounds with Tetradymite structure • • • • • . • • • • • • • 183 §4. Properties of AYBi'l Compounds • • • • • • • • • 186 § 5. Preparation Methods • • • • • • • • • • • • • • • • • 199 vii viii CONTENTS §6. Systems BasedonA;'B~ Compounds • • • • • • • 201 § 7. AIVB VI-A;'Bi'l Systems. • • • • . . • • • • . • • • 23 0 Literature Cited. • • • • . • . . • • • . • • • • • • . • • . • 240 Index . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 247 CHAPTER I A11 COMPOUNDS BVI 1. CRYSTAL STRUCTURE Almost all compounds of the All B VI type crystallize in such a manner that each atom of one element is located at the center of a regular tetrahedron, the apices of which are occupied by atoms of the other element. Two possible structures can be formed from such tetrahedra: the sphalerite (cubic type) and the wurtzite (hex agonal) type. The sphalerite structure is very similar to the struc ture of diamond, but it differs from the latter by the alternation of atoms of two different elements. In the sphalerite structure, the atoms of one elementare located at the sites of an fcc lattice, while the atoms of the second element occupy centers of four (out of a total of eight) small cubes (Fig. 1). The space group is F43m (Tj ) . The coordination number is 4 for atoms of both elements. Figure 2 shows the wurtzite structure. Its space group is P63mc (C~v). Again the coordination number is 4 for atoms of both elements. The crystal structures of the AIIB VI-type compounds are listed in Table 1 [1-15]. The sphalerite and the wurtzite structures are very similar. This similarity is due to the same number of atoms in the first and second coordination spheres. In both structures, each atom in the second coordination sphere is surrounded by 12 atoms of the same element; there are only certain differences in the distri bution of the atoms, which are due to the different paclting in cubic and hexagonal crystals. The basic difference between the two 1