Plasma Processing for VLSI
- 1st Edition, Volume 8 - June 7, 1984
- Latest edition
- Editors: Norman G. Einspruch, Dale M. Brown
- Language: English
VLSI Electronics: Microstructure Science, Volume 8: Plasma Processing for VLSI (Very Large Scale Integration) discusses the utilization of plasmas for general semiconductor… Read more
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Description
Description
VLSI Electronics: Microstructure Science, Volume 8: Plasma Processing for VLSI (Very Large Scale Integration) discusses the utilization of plasmas for general semiconductor processing. It also includes expositions on advanced deposition of materials for metallization, lithographic methods that use plasmas as exposure sources and for multiple resist patterning, and device structures made possible by anisotropic etching. This volume is divided into four sections. It begins with the history of plasma processing, a discussion of some of the early developments and trends for VLSI. The second section, Deposition, discusses deposition techniques for VLSI such as sputtering metals for metallization and contacts, plasma-enhanced chemical vapor deposition of metals and suicides, and plasma enhanced chemical vapor deposition of dielectrics. The part on Lithography presents the high-resolution trilayer resist system, pulsed x-ray sources for submicrometer x-ray lithography, and high-intensity deep-UV sources. The last part, Etching, provides methods in etching, like ion-beam etching using reactive gases, low-pressure reactive ion etching, and the uses of inert-gas ion milling. The theory and mechanisms of plasma etching are described and a number of new device structures made possible by anisotropic etching are enumerated as well. Scientists, engineers, researchers, device designers, and systems architects will find the book useful.
Table of contents
Table of contents
List of Contributors
Preface
Chapter 1 The History of Plasma Processing
I. Introduction
II. Early Developments
III. Introduction of Plasma Processing to Semiconductor Manufacturing, 1971-1978
IV. Full-Scale Commitment to Dry-Process Technology, 1978-1983
V. Challenges and Opportunities for Plasma Technology, 1983-1988
References
Part A Deposition
Chapter 2 Sputtering for VLSI
I. Introduction
II. Contact Metallization
III. Diffusion Barriers
IV. Schottky Diode Metallization
V. Cosputtered Aluminum Alloys
VI. Refractory Suicides in Gate Metallization
VII. Film Stress
VIII. Dielectrics
IX. Die Attach
X. Summary and Future Directions
References
Chapter 3 Plasma-Enhanced Chemical Vapor Deposition of Transition Metals and Transition Metal Silicides
I. Introduction
II. Plasma-Enhanced Deposition
III. Summary
References
Chapter 4 Plasma-Enhanced Chemical Vapor Deposition of Dielectrics
I. Introduction
II. General Principles
III. Specific Materials
IV. Equipment for PECVD of Inorganic Dielectrics
V. Summary
References
Part B Lithography
Chapter 5 Trilayer Resist
I. Introduction
II. Plasma Processing
III. Limitations of Single-Layer Resist
IV. Formation of the Process Etch Mask
V. Utilization of the Process Mask
VI. Options to Trilayer Resist
VII. Summary
References
Chapter 6 Plasma Sources for X-Ray Lithography
I. Introduction
II. X-Ray Lithography
III. X-Ray Source Requirements
IV. Electron-Impact X-Ray Sources
V. Synchrotron X-Radiation Sources
VI. Plasma X-Ray Sources
VII. Conclusion
Appendix. X-Ray Source Characterization
References
Chapter 7 Plasma Sources for Deep-UV Lithography
I. Introduction
II. General Requirements for Deep-UV Lithographic Sources
III. Description of Sources
IV. Conclusions
References
Part C Etching
Chapter 8 Basic Principles of Plasma Etching for Silicon Devices
I. Introduction
II. Principle of Isotropic and Anisotropic Etching
III. Plasma and Surface Chemistry
IV. Selectivity in Plasma Etching
V. Etching in Plasmas That Produce Free Fluorine
VI. Etching of Organic Material in Oxygen-Based Plasmas
VII. Etching in Plasmas That Produce Fluorocarbon Radicals
VIII. Etching in Plasmas That Produce Chlorine and Bromine Atoms
IX. Hydrogen Plasma Etching
References
Chapter 9 High-Pressure Etching
Nomenclature
I. Introduction
II. Equipment
III. Plasma Properties
IV. Processes for Specific Materials
V. Conclusions
References
Chapter 10 Reactive Ion Etching
I. Introduction
II. General Principles
III. Process Parameter Effects
IV. Specific Materials and Structures
V. Equipment Considerations
VI. Summary
References
Chapter 11 Ion-Beam Etching (Milling)
I. Introduction
II. Physics of Ion-Beam Etching
III. Techniques and Problems of Ion-Beam Etching
IV. Applications
V. Ion-Beam Etch Equipment
VI. Summary and Conclusions
References
Chapter 12 Reactive Ion-Beam Etching
I. Introduction
II. Ion Sources and Operation
III. Applications
IV. Chemistry and Physics of Etching Reactions
V. Summary and Conclusions
References
Chapter 13 Plasma Diagnostics and End-Point Detection
I. Introduction
II. Measurement Techniques
III. Plasma Parameters
IV. End-Point Detection
V. Summary
References
Chapter 14 Emerging Etching Techniques
I. Introduction
II. High-Rate Reactive Ion Etching Using a Magnetron Discharge
III. Gate-Oxide Breakdown
IV. Atomic and Molecular Beam Etching
V. UV-Light Irradiation Etching
References
Chapter 15 Advanced Device Structures Fabricated with Anisotropic Dry Etching
I. Introduction
II. Basic Approaches
III. Device Components
IV. Applications
V. Conclusions
References
Index
Contents of Other Volumes
Product details
Product details
- Edition: 1
- Latest edition
- Volume: 8
- Published: September 25, 2014
- Language: English
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