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Analogies in Optics and Micro Electronics: Selected Contributions on Recent Developments PDF

256 Pages·1990·8.437 MB·English
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ANALOGIES IN OPTICS AND MICRO ELECTRONICS Analogies in Optics and Micro Electronics Selected Contributions on Recent Developments Edited by Willem van Haeringen Eindhoven University of Technology, Eindhoven, The Netherlands and Daan Lenstra Eindhoven University of Technology and University of Leiden, The Netherlands KLUWER ACADEMIC PUBLISHERS DORDRECHT / BOSTON / LONDON Library of Congress Cataloging in Publication Data Analogies in optics and micro electronIcs: selected contributions on recent developments I edited by Willem van Haeringen and Daan Lenstra. p. cm. 1. Optics. 2. Microelectronics. I. Haeringen, Willem van, 1933- II. Lenstra, Daan, 1947- TA1675.A49 1990 535--dc20 90-4175 ISBN-13: 978-94-010-7400-1 e-ISBN-13: 978-94-009-2009-5 DOl: 10.1007/978-94-009-2009-5 Published by Kluwer Academic Publishers, P.O. Box 17, 3300 AA Dordrecht, The Netherlands. Kluwer Academic Publishers incorporates the publishing programmes of D. Reidel, Martinus Nijhoff, Dr W. Junk and MTP Press. Sold and distributed in the U.S.A and Canada by Kluwer Academic Publishers, 101 Philip Drive, Norwell, MA 02061, U.S.A. In all other countries, sold and distributed by Kluwer Academic Publishers Group, P.O. Box 322, 3300 AH Dordrecht, The Netherlands. Printed on acid-free paper All Rights Reserved © 1990 by Kluwer Academic Publishers Softcover reprint of the hardcover 1st edition 1990 No part of the material protected by this copyright notice may be reproduced or utilized in any form or by any means, electronic or mechanical, including photocopying, recording or by any information storage and retrieval system, without written permission from the copyright owner. CONTENTS Preface vii P ART I: PRINCIPLES AND BASIC CONCEPTS 1 1. Playing with electrons and photons in rings 3 D. Lenstra and W. van Haeringen 2. What to expect from similarities between the Schrodinger and Maxwell equations 21 M. Kaveh 3. Synergetics as a theory of analogous behavior of systems 35 H. Haken 4. Density of states of electrons and electromagnetic waves in one-dimensional random media 49 P. ErdOs and Z. Domanski 5. Classical light waves and spinors 69 R. Bhandari PART II: COHERENT OPTICS 83 6. Towards observation of Anderson localization of light 85 M.P. van Albada, A. Lagendijk and M.B. van der Mark 7. Photon localization: the inhibition of electromagnetism in certain dielectrics 105 S. John 8. Photonic band structure 117 E. Yablonovitch 9. Optical level crossings 135 J.P. Woerdman and R.J.C. Spreeuw 10. Berry's phases in optics 151 R. Y. Chiao vi CONTENTS PART III: COHERENT ELECTRONICS 163 11. Aharonov-Bohm oscillations and non-local electronic conduction 165 C. Van Haesendonck 12. Phase-sensitive voltage measurements 185 M. Biittiker 13. Quantum point contacts and coherent electron focusing 203 H. van Houten and C. w.J. Beenakker 14. Charge build-up and intrinsic bistability in resonant tunneling 227 L. Eaves 15. Electrons as guided waves in laboratory structures: strengths and problems 243 R. Landauer Index 259 PREFACE This book gives an account of a number of recent developments in two different subfields of research, optics and micro--electronics. The leading principle in presenting them together in one book is the striking similarity between a variety of notions in these two research areas. We mention in this respect tunneling, quantum interference and localization, which are important concepts in quantummechanics and more specifically in condensed matter physics. Miniaturization in solid state engineering has led to new phenomena in which these concepts play their significant roles. As it is the wave character of electrons which is strongly emphasized in these phenomena one's attention is quite naturally directed to the field of optics in which the above quantum-mechanical notions all seem to have their direct classical wavemechanical counterparts. Both micro--electronics and optics have been and still are in a mode of intensifying activity. The possibilities to technically "translate" devices developed within one research field to similar devices in the other field are strongly increasing. This opens, among other things, a door leading to "quantummechanics" on a macroscopic scale with visible light under relatively easily accessible experimental conditions, or to "wave optics in the domain of solid state physics. Thinking in II terms of analogies is important anyhow, but it is especially the cross-fertilization between optics and micro--electronics which according to the editors will lead to deepened insights and a new type of technology. We have chosen for a presentation in which a restricted number of selected researchers in both fields sketch developments to which they have significantly contributed themselves. This will make the book of utmost importance for workers in the respective fields. Furthermore, the didactical skills of the contributing authors guarantee accessibility of the book to a much broader group of readers, e.g. graduate students, physicists and electrical engineers who are not particularly specialized in this area, but wish to obtain an overview. The book contains fifteen presentations which we have classified into three groups: I. principles and basic concepts, II. coherent optics and III. coherent electronics. Apart from giving an important collection of new articles on recent developments in optics and micro electronics, the objective of the editors has been to demonstrate the apparent potentialities of thinking in terms of analogies. Many interesting other analogies such as, e.g., between superconducting and optical devices are not dealt with in the present volume. Also several important earlier developments in the field of electron beam "optics" and X-ray diffraction in crystals have not been covered. For a book of this set up and size it is impossible to give a complete account. So, the outline of this first edited work on analogies in optics and micro--electronics reflects very much the opinions and preferences of the editors. We would like to express our sincere gratitude to Ria Coopmans-van Basten for vii viii PREFACE the secretarial and technical support she gave with great commitment to the book. Special thanks also to Ria Groenendijk and Brigitte Senden for their assistance at critical moments during the final stage of the project. May this book serve to intensify the "analogy" kind of approach, thus leading to even more cross-fertilization and if possible new fascinating results in the borderline between two important technologies in the fields of optics and micro electronics. Eindhoven, Spring 1990 Willem van Haeringen Daan Lenstra PART I PRINCIPLES AND BASIC CONCEPTS PLAYING WITH ELECTRONS AND PHOTONS IN RINGS Daan Lenstra and Willem van Haeringen A "one-dimensional" ring configuration is a simple non-trivial system, particularly suited for a theoretical study of wave propagation dynamics under the influence of an external driving force. This ring system, although initially designed as an academic play field with non-interacting model electrons, becomes most relevant and experimentally accessible in the case of real-world optics. 1. INTRODUCTION A ring is a very interesting system which combines two useful properties in an intriguing if not controversial way: it is a finite system with regard to its dimensions but endless for waves or particles traveling around and around. In optics both the ring resonator and the ring laser have been thoroughly investigated which has led to many applications related to their subtle and rich phenomenology. We mention 'the laser gyroscope [1], bistability effects in ring lasers [2] and, more recently, 1f"-phase jumps [3] and optical bandstructures in ring resonators [4], the latter item being adressed to in the chapter by Woerdman and Spreeuw (Chap.g). In submicron electronics the ring system has been used for measuring Aharonov-Bohm type magneto-resistance oscillations [5]. The chapter by Van Haesendonck is devoted to this and other nonlocal effects (Chap.l1). Supercond ucting rings with Josephson junctions have been thoroughly investigated [6,7]. For the theoretical physicist the ring has become an important model system for studying fundamental properties of electron dynamics and electrical conduction as it avoids the necessity of introducing ad hoc boundary conditions which are to reflect externally controlled fluxes of incoming or outgoing particles (or waves). On the one hand, a ring measures precisely one primitive cell, but on the other hand it is an infinite periodic system as well. Particles or waves which are traveling around in the ring can be accelerated due to an external force. Furthermore, they can be scattered (in fact, only back scattered in a ID ring) and thus a nontrivial dynamics can be created. We will consider only elastic scattering, i.e., described by a certain structure in the potential energy function (electrons) or refractive index (photons). For these scattering processes the coherence of the waves before, during and after scattering is fully conserved. This is an interesting limiting situation in case of electrons because it resembles the situation at very low temperatures, where the increasing amount of experimental evidence shows that electrical conduction cannot be fully described anymore in terms of diffusion of carriers, but should rather be treated in terms of coherent wave propagation [8]. The chapters by Van Haesendonck (Chap.l1), Biittiker (Chap.12) and van Houten and Beenakker (Chap.13) deal with this regime, while also the concept of resonant tunneling, studied by Eaves in Chap.14, implies coherent propagation of charge 3 W. van Haeringen and D. Lenstra (eds.), Analogies in Optics and Micro Electronics, 3-19. @ 1990 Kluwer Academic Publishers. 4 D. LENSTRA AND W. VAN HAERINGEN carriers. One could argue that analogies between electrons and light can best be studied on the level of the Dirae and Maxwell equations. However, it is well known that the physics of electrons in modern semieonducting materials and structures can succesfully be described within a SchrOdinger-equation framework. It would therefore be extremely instructive and useful if existing analogies between eertain aspects of optics and micro-electronics can be discussed within the framework of a Schrodinger equation covering both cases. Therefore, in Sec.2 we take up that ehallenge and arrive at the conclusion that photons can indeed adequately be dealt with by means of a non-relativistic Schrodinger equation. In Sec.3 we use the ring configuration in order to present a unified treatment of wave dynamics in response to a slowly varying external perturbation. We find general properties of the eigenstates and corresponding eigenvalues and we treat the dynamical response in the adiabatic approximation. In Sec.4 we discuss the experimental feasibility of Bloch oscillations in a ring. By estimating the various time scales involved in such an experiment, we conclude that the best opportun ities for observing Bloch oscillations are found in the optical ring system. Non-adiabatic response, involving transitions between energy bands, is discussed in Sec.5. In this regime we can study, at least theoretically, the fundamental problem of coherent (i.e. temperature T = OK) wave dynamics due to relatively large driving fields, without performing any of the usual approximations such as linear-response theory or Boltzmann-equation approach. In the case of electrons, the solution of the time-dependent Schrodinger equation turns out to be chaotic, which is related to the fact that the time-dependent phases (modulo 27r) in the one-electron wave function generally don't repeat themselves after each roundtrip in a regular or commensurate way. This gives the system self randomizing properties due to pseudo-stochastics, that is, on short time scales. The intrinsic coherence of the mUltiply scattered waves becomes noticeable on longer time scales as a weak form of localization. 2. A SCHRODINGER EQUATION FOR PHOTONS Since one of our aims is to exploit the analogy between electron waves and optical waves, it would be beneficial to deal with one and the same equation valid for either case. Confining ourselves to the rich variety of electron propagation phenomena which are succesfully described by a Schrodinger equation, for which the solutions and their properties are well known, we want to investigate the possibility of describing photons by means of a Schrodinger equation. In order to be able to study dynamical properties, it has to be a time-dependent Schrodinger equation. The derivation will quite naturally lead to the quantity which plays the role of potential; this will make it possible and easy to "translate" many typical quantummechanical results directly into the field of optics [9]. Our starting point is the wave equation for the electric-field component E in a eonfiguration involving dielectric materials, (1) For simplicity we consider the scalar case only; it is possible, however, to include the vector nature of the light and draw a parallel between the polarization of light

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