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Plasma Diagnostics. Discharge Parameters and Chemistry PDF

458 Pages·1989·9.193 MB·English
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Plasma-Materials Interactions A Series Edited by Orlando Auciello Daniel L. Flamm Microelectronics Center of AT&T Bell Laboratories North Carolina and Murray Hill, New Jersey North Carolina State University Research Triangle Park, North Carolina Advisory Board J. L. Cecchi W. O. Hofer Plasma Physics Laboratory Institut fiir Grenzflachenforschung Princeton University und Vakuumphysik Princeton, New Jersey Julich, Federal Republic of Germany A. E. deVries N. Itoh FOM-Instituut voor Department of Crystalline Atoom-En Molecuulfysica Materials Science A msterdam- Watergraafasmeer Nagoya University The Netherlands Nagoya, Japan H. F. Winters G. M. McCracken IBM, Almaden Research Center Culham Laboratory San Jose, California Abingdon, Oxfordshire United Kingdom A list of titles in this series appears at the end of this volume. Plasma Diagnostics Volume 1 Discharge Parameters and Chemistry Edited by Orlando Auciello Microelectronics Center of North Carolina and North Carolina State University Research Triangle Park, North Carolina Daniel L. Flamm A T&T Bell Laboratories Murray Hill, New Jersey ® ACADEMIC PRESS, INC. Harcourt Brace Jovanovich, Publishers Boston San Diego New York Berkeley London Sydney Tokyo Toronto Copyright © 1989 by Academic Press, Inc. All rights reserved. No part of this publication may be reproduced or transmitted in any form or by any means, electronic or mechanical, including photocopy, recording, or any information storage and retrieval system, without permission in writing from the publisher. ACADEMIC PRESS, INC. 1250 Sixth Avenue, San Diego, CA 92101 United Kingdom Edition published by ACADEMIC PRESS, INC. (LONDON) LTD. 24-28 Oval Road, London NW1 7DX Library of Congress Cataloging-in-Publication Data Plasma diagnostics. (Plasma-materials interactions) Includes bibliographies and index. Contents: v. 1. Discharge parameters and chemistry —v. 2. Surface analysis and interactions. 1. Plasma diagnostics. I. Auciello, Orlando, Date- II. Flamm, Daniel L. III. Series. QC718.5.D5P54 1988 530.41 87-35161 ISBN 0-12-067635-4 (v. 1) ISBN 0-12-067636-2 (v. 2) Printed in the United States of America 89 90 91 92 9 8 7 6 5 4 3 2 1 Contributors Numbers in parentheses refer to the pages on which the authors' contributions begin. J. M. COOK (313), AT&T Bell Laboratories, Murray Hill, New Jersey 07974 J. F. COUDERT (349), Laboratoire Ceramiques Nouvelles, UA 320 CNRS, University of Limoges, Limoges, France V. M DONNELLY (1), AT&T Bell Laboratories, Murray Hill, New Jersey 07974 H. F. DYLLA (185), Plasma Physics Laboratory, Princeton University, Princeton, New Jersey 08544 P. FAUCHAIS (349), Laboratoire Ceramiques Nouvelles, UA 320 CNRS, University of Limoges, Limoges, France NOAH HERSHKOWITZ (114), Nuclear Engineering and Engineering Physics Department, University of Wisconsin-Madison, Madison, Wisconsin 53706 H. MEUTH (239), Department of Electrical Engineering and Computer Science, University of California, Berkeley, California 94720 TERRY A. MILLER (313), Department of Chemistry, Ohio State University, Columbus, Ohio 43210 E. SEVILLANO (239), MIT Plasma Fusion Center, Cambridge, Massachusetts 02139 M. VARDELLE (349), Laboratoire Ceramiques Nouvelles, UA 320 CNRS, University of Limoges, Limoges, France M. J. VASILE (185), AT&T Bell Laboratories, Murray Hill, New Jersey 07974 JOHN F. WAYMOUTH (47), GTE Lighting Products, Danvers, Massachusetts 02254 ix Preface The study of plasma-material interactions has evolved into an important and dynamic field of research. An understanding of the basic physical and chemical processes underlying these interactions is vital to the development of microelectronics, surface modification, fusion, space, and other key technologies of our age. Plasma processing is a critical technology for leading-edge microelectronics. For example, ultra large scale integrated circuits (ULSI) cannot be manufactured without plasma-assisted etching and plasma chemical vapor deposition. Similarly, the various plasma- surface phenomena—physical sputtering, chemical etching, particle trap­ ping in solid walls etc.—must be understood and controlled to achieve self-sustained fusion reactions in future commercial power plants. Plasma interactions with surfaces of spaceships can produce harmful degradation, such as the undesirable etching of thermal blankets observed in the cargo bay of the Space Shuttle. These effects could jeopardize long-term missions in space. All of these problems are now being investigated by scientists and engineers around the world. Unfortunately, scientific and technical information in these diverse fields is often published in journals aimed at a narrow specialized audience. One of the chief goals of this series on "Plasma-Materials Interactions", which we are now initiating, is to provide an interdisciplinary forum. We hope to disseminate knowledge of basic and applied physicochemical processes and plasma-processing art to the global community. The series is structured to make this information readily accessible to scientists, engineers, students and technical personnel in universities, industry, and national laboratories. We consider plasma-materials interactions to be one of the pivotal fields of research that will contribute to the technological revolution now under way. Therefore, we hope that this series will encourage the pursuit of new ideas and expand the horizons of science and technology in allied interdisci­ plinary fields. Diagnostics and characterization techniques are prerequisites for under­ standing plasmas and solid surfaces exposed to plasmas. Unfortunately the XI xii Preface necessary know-how is scattered throughout the literature, often in a form that is difficult to use. Consequently, we begin this series with an authorita­ tive and up-to-date treatment of plasma and surface diagnostics written for an interdisciplinary audience. The authors are renowned specialists who explain how to set up, make, and interpret measurements and how to assess the validity of diagnostic data and detect complications. Finally, they present the theoretical background necessary to understand each technique with references to recent literature. Because the material is fairly compre­ hensive, the book is divided into two volumes. Volume 1 contains seven chapters on the important diagnostic techniques for plasmas and details their use in particular applications. This part includes (1) optical diagnostics for low-pressure plasmas and plasma processing, (2) plasma diagnostics for electrical discharge light sources, (3) Langmuir probes, (4) mass spectroscopy of plasmas, (5) microwave diagnostics, (6) paramagnetic resonance diagnostics, and (7) diagnostics in thermal plasma processing. Volume 2 covers diagnostics of surfaces exposed to plasmas and includes chapters on (1) quartz crystal microbalances for studies of plasma-surface interactions, (2) elemental analysis of treated surfaces by electron and ion spectroscopies, (3) spectroscopic ellipsometry in plasma processing, (4) ion beam analysis of plasma-exposed surfaces (Rutherford backscattering, elas­ tic recoil detection, particle-induced X-ray emission and nuclear reaction analysis), (5) the interpretation of plasma probe data in fusion experiments, and (6) non-destructive photoacoustic and photothermal techniques for the analysis of plasma-exposed surfaces. We hope that these, and subsequent books in this series, will be valuable to experts and newcomers alike. "Plasma-Materials Interactions" volumes on plasma etching technology and on plasma deposition and etching of polymers are now in press. We would welcome your suggestions for future volumes. Orlando Auciello Daniel L. Flamm January, 1989 1 Optical Diagnostic Techniques for Low Pressure Plasmas and Plasma Processing V. M. Donnelly AT&T Bell Laboratories Murray Hill, New Jersey I. Introduction 1 II. Plasma-Induced Optical Emission 3 III. Absorption Spectroscopy 15 A. Ultraviolet-Visible Absorption 15 B. Infrared Absorption 17 IV. Laser Techniques 19 A. Laser-Induced Fluorescence (LIF). 19 B. Raman Scattering 28 C. Coherent Anti-Stokes Raman Spectroscopy (CARS) 29 D. Tunable Infrared Laser Absorption 30 E. Optogalvanic Effects 34 V. Optical Techniques for Plasma-Surface Interactions 35 A. Laser Interferometry 36 B. Ellipsometry 37 C. Second Harmonic Generation (SHG) 39 D. Laser Raman Scattering From Surfaces 40 E. Surface Absorption and Photoacoustic Spectroscopy 41 VI. Summary 42 VII. Acknowledgments 43 References 43 I. Introduction Advances in microelectronics technology over the last two decades have exceeded even the most optimistic expectations. The rapid progress in the manufacturing of complex devices such as dynamic random access memory integrated circuits has been made possible, in part, by advances in process­ ing and process control. Low pressure glow discharges are used in many of PLASMA DIAGNOSTICS 1 Copyright © 1989 by Academic Press, Inc. Discharge Parameters and Chemistry All rights of reproduction in any form reserved. ISBN 0-12-067635-4 2 V. M. Donnelly these steps (Flamm, Donnelly, and Ibbotson, 1984). For example, radio- frequency plasmas in SiH /N 0 and SiH /NH are used to deposit Si0 4 2 4 3 2 and silicon nitride thin films for applications including gate-oxides, device isolation and encapsulation, diffusion masks, and etch masks. Oxygen atoms formed in 0 discharges are employed to clean wafer surfaces and 2 remove photoresists. However, plasma processing has had the largest im­ pact in silicon integrated circuit technology by making it possible to etch submicron-sized features with vertical side walls in silicon, metals, and insulators. The precise control of both etching and deposition processes often requires some in situ diagnostic probe to measure the rates or to detect the endpoint when a film has been etched through to expose a sensitive, underlying material. Several optical techniques have been success­ fully applied to this task. Empirical optimization of plasma parameters (gas composition, pressure, power, etc.) has produced many successful etching and deposition "recipes." However, with the advent of increasingly sophisticated diagnostic tech­ niques and computer modeling, it is now possible to obtain very detailed information on the chemistry and physics of these processing plasmas and their interactions with surfaces. Of all the diagnostics, optical techniques have yielded the most detailed information. With the availability of multi­ channel detectors, narrow bandwidth, tunable lasers, Fourier transform IR, and other state-of-the-art equipment, many studies have already revealed details of ion dynamics, radical formation and loss processes, and electron impact excitation mechanisms. More fundamental studies (Donnelly, Ibbotson, and Flamm, 1984) de­ signed to elucidate mechanisms can be placed in two categories. Since the plasma is a very complex chemical environment, one ex situ technique is to isolate part of the etching or deposition process from the discharge. Discharge flow tube (Donnelly and Flamm, 1980; Flamm, et al., 1981; Mucha et al, 1981; Ryan and Plumb, 1984; Danner and Hess, 1986) and molecular beam (Coburn, 1985) experiments have determined many of the reactions of both neutral and charged species with other gas-phase species as well as with materials exposed to the discharge. A second, in situ approach employs discharge conditions comparable to those in the plasma processing environment but with equipment designed to be amenable to various diagnostic probes. While these studies are often carried out under less well controlled conditions, they are nonetheless extremely valuable because they provide information more closely related to actual processing conditions. Optical probes are particularly well suited for in situ plasma diagnostic studies because they are nonintrusive, species-selective, and can yield both space- and time-resolved information. This paper will review relevant Optical Diagnostic Techniques 3 optical diagnostic techniques and cite examples of applications to process monitoring and fundamental studies. While many of the techniques de­ scribed can be applied to other types of plasmas (e.g., thermal plasmas and microwave discharges), most of the examples are of low pressure, radio frequency discharges of the type used in microelectronics materials process­ ing. II. Plasma-Induced Optical Emission Optical emission eminating from gas discharges has long been used as a qualitative diagnostic of plasma physics and chemistry. The segmenting of emission into bright and dark regions provides information on the motions of ions and electrons in response to the spatially varying electric fields, while the identification of the spectrally resolved features establish the presence of radicals and ions formed by reactions in the discharge. The apparatus required for this technique is one of the least complicated. It requires a monochromator to disperse the plasma emission, a set of optics to image light from the discharge onto the detector, and a photode- tector to measure the dispersed fluorescence. A 0.25 m focal length monochromator can provide ~ 0.05 nm resolution, which is sufficient for most studies. When resolution of atomic fine structure, molecular rotational levels, or detailed line shape measurements are necessary, a long focal length monochromator (e.g., 1 m focal length, ~ 0.01 nm resolution) or Fabre-Perot interferometer (~ 0.0005 nm resolution) can be used. The Fabre-Perot interferometer must be used in conjunction with a monochro­ mator, since the scanning range of an interferometer is typically less than 1 nm. Monochromatic light emerging from the exit sht of the monochromator can be detected with a photomultiplier tube used in an analog (current measuring) or digital (photon counting) mode. Alternatively, the exit sht can be replaced with an optical multichannel analyzer (OMA) placed in the image plane of the exit sht. The advantage of an OMA is that a portion of the emission spectrum (defined by the monochromator dispersion) can be recorded simultaneously without scanning the monochromator. The most sensitive OMAs have a quantum efficiency nearly as good as photomulti­ plier tubes and so can provide much faster data collection. Most species of interest emit in the spectral region between 200 and 900 nm, where GaAs and S-20 detectors have adequate sensitivity. Both shorter and longer wavelength detectors and optics are available. Below - 190 nm, vacuum enclosures are required to prevent absorption by 0 . Hence, studies in the 2 region are less common. Longer wavelength (> 900 nm) emissions from 4 V. M. Donnelly electronic transitions are relatively weak and less common and hence not as useful for most applications. IR emission from vibrationally excited levels can provide useful information. However, signals are many orders of magnitude weaker than visible-UV emission, while blackbody background emission requires all surfaces "seen" by the IR-detector to be cooled, preferably to liquid nitrogen temperature. Consequently, very few studies have been published in the IR region. Light from the discharge can be imaged onto the monochromator en­ trance slit with UV-grade fused silica lenses and UV-coated aluminum mirrors for best average response between 200 and 900 nm. Care should be taken in determining what region of the discharge is imaged onto the slit, since this carries added information and is important in comparing studies under various operating conditions and, in particular, in different reactor geometries. Spectrally resolved optical emission has been reported for a variety of discharges, under conditions employed in both etching and deposition. For example, emission from atomic fluorine is observed from CF /0 dis­ 4 2 charges (Harshberger et al., 1977; Flamm, 1978; Donnelly et al., 1984). Intensity increases with 0 content (up to - 50% 0 ) and decreases with 2 2 the area of silicon exposed to the plasma. From these observations one concludes that oxygen consumes CF^. species to liberate F-atoms, which in turn react with silicon to form volatile products. Plasma-induced emission can arise from electron impact excitation, A + e-+A* + e, (1) electron impact dissociation, AB + e ->A* + B + e, (2) or an ion impact process, A++ e{ + M) ->,4*( + M), (3) where A and B are atoms or molecules, * indicates the excited, emitting species, and e{ + M) may be a neutral species, a negative ion, an electron plus a third body, or a surface. Each of these processes has been found to occur in low pressure glow discharges. For example, reaction (1) is responsi­ ble for emission from excited F-atoms in CF /0 discharges (Gottscho and 4 2 Donnelly, 1984), and also from Cl in Cl discharges under most conditions 2 (Gottscho and Donnelly, 1984), while process (2) has been observed by time-resolved emission in the momentary cathode sheath of a radio- frequency Cl discharge (Gottscho and Donnelly, 1984; Donnelly et al., 2 1985; Flamm and Donnelly, 1986). Excitation of H-atoms in a H -DC 2 discharge has been ascribed in part to reaction (3) (Capelli et al., 1985; Benesch and Li, 1985).

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