半導體業界所使用之超高純度材料

INTRODUCTION

STUDY GOALS AND OBJECTIVES

The objective of "Ultrapure Materials for the Semiconductor Industry" (an updated BCC technical/marketing report) is to present a detailed view of the complex, dynamic nature of the U.S. semiconductor market for these chemicals, water, and gases. This report seeks to ascertain how growth in this market relates to demand for semiconductors, and how this market is influenced by regulatory, technological and economic factors. It also provides the information necessary for evaluating projections relating to the U.S. ultrapure materials market.

REASONS FOR DOING THE STUDY

The semiconductor industry contains key technologies for any industrialized country, and its output is subject to exhaustive analysis and quantification. However, little comprehensive market information exists on the ultrapure materials used to manufacture semiconductors and related products. This updated report fills that knowledge gap by providing information on supply and demand, growth rates, market shares, potential markets, new technologies, current research, environmental issues and profiles of key participants.

HISTORY OF THE MARKET

Born out of a need to quickly process large amounts of information, the semiconductor industry has come of age since the world's first electronic computer deciphered codes during World War II. The solid-state electronics age was launched in 1947 with the development of the transistor, and growth was aided with the 1959 discovery of the integrated circuit.

From these discoveries emerged the semiconductor industry that throughout the 1970s and 1980s designed, packaged and sold separate transistors, Darlingtons and other simple combinations, as well as integrated circuits made on dies, i.e., single pieces of silicon. As the semiconductor industry grew, however, the distinction between component and circuit became less so, and increasingly pure materials were required from suppliers. In response, separate divisions and companies emerged to meet the demand.

The birth of multichip module (MCM) interconnects, where the semiconductor die is mounted directly onto tiny printed circuit boards made of ceramic, led to newer photolithographic processes. These required ultrapure, rather than ordinary materials, to produce finer MCM interconnects. MCMs do not need processes and materials related to doping and junction formation, but they do use many substrate materials. The falling-out stage that likely will leave one room temperature and one high-temperature MCM interconnect technology, has not yet come to this industry.

By 2004 or shortly thereafter, miniaturization of interconnects should catch up with miniaturization of semiconductor dies as progress is made in connecting dies to interconnects in MCMs. The success of the Intel P-6 or Pentium Pro (a two-die module) in finding a mass market, in comparison with its single-die precursors, the Intel Pentium and the Motorola Power PC, heralded the beginning of that process.

If computers using the Pentium Pro microprocessor appear in discount stores (although the first ones will be distributed to businesses), and if the next-generation microprocessor also has two or more dies, then the trend toward MCMs can be considered as established.

SCOPE AND FORMAT

This report organizes information from diverse sources into a cohesive unit that includes an overview of the industry, industry structure, and an analysis of market demand. Industry structure addresses the competitive aspects of the industry and profiles key companies involved in supplying ultrapure chemicals, water and gases to the semiconductor and related industries.

The market analysis identifies major products, applications and technologies, as well as patent abstracts that represent many R&D trends and that illustrate areas of company activity. The analysis also includes estimates of current and projected U.S. market size for the ultrapure materials considered in this report. All values and projections are made in terms of current dollars and represent real growth over the 5-year period covering 2002 to 2007, unless otherwise noted.

METHODOLOGY AND INFORMATION SOURCES

The methodologies used in this report include extensive library research and information from internal BCC files, as well as telephone interviews with trade associations and key representatives from the leading suppliers of ultrapure materials to the semiconductor industry. The report also includes an online search of databases covering existing literature, as well as an evaluation of government statistics, company activities, state-of-the-art technology, and patents. Since this report revises, expands, and updates a previous BCC report (C-152R), it contains some historical and background information. This information conforms to the newer BCC format and the more-focused objectives of this report.

CONTRIBUTION OF THE STUDY AND FOR WHOM

This updated study consolidates a range of technical and industrial information into a comprehensive technical/marketing report that should aid R&D personnel. It provides in-depth information and state-of-the-art technological evaluations for decision making by those involved in, or considering becoming involved in, the supply of ultrapure chemicals, water or gases to the semiconductor and related industries.

The study can assist clients in strategic planning, acquisition analysis, technology analysis, commercial development of new products, and analysis of competitors' strategies, strengths, weaknesses, pricing, market share and profitability.

TABLE OF CONTENTS

INTRODUCTION

• STUDY GOALS AND OBJECTIVES
• REASONS FOR DOING THE STUDY
• HISTORY OF THE MARKET
• SCOPE AND FORMAT
• METHODOLOGY AND INFORMATION SOURCES
• CONTRIBUTION OF THE STUDY AND FOR WHOM
• RELATED BCC WORK CREDENTIALS
• BCC ON-LINE SERVICES
• DISCLAIMER

SUMMARY

• Summary Table:
  U.S. VALUE OF ULTRAPURE CHEMICALS, WATER, AND GASES USED IN SEMICONDUCTORS, THROUGH 2007 ($ MILLIONS)
• Summary Figure:
  U.S. VALUE OF ULTRAPURE CHEMICALS, WATER, AND GASES USED IN SEMICONDUCTORS, 1992-2007 ($ MILLIONS)
  • CHEMICALS
  • WATER SYSTEMS
  • BULK, SPECIALTY GASES

ULTRAPURE SEMICONDUCTOR MATERIAL OVERVIEW

• ULTRAPURE SEMICONDUCTOR MATERIAL OVERVIEW
• Table 1. ULTRAPURE CHEMICALS, WATER AND GASES USED IN SEMICONDUCTOR MANUFACTURING
  • SEMICONDUCTOR MANUFACTURE
    • MATERIAL PREPARATION
    • CRYSTAL GROWTH
    • WAFER FABRICATION
    • PACKAGING
  • SEMICONDUCTOR CONTAMINATION
    • EFFECTS OF CONTAMINANTS
• Device Processing Yield
• Device Performance
• Device Reliability
• CONTAMINATION TYPES
• Particles
• Metallic Ions
• Inorganic Chemicals
• Dissolved Organics and Bacteria
• MAJOR SOURCES OF SEMICONDUCTOR CONTAMINATION
• Feedstocks
• Fixtures
• Process
• Effluents
• Information
• Maintenance
• Personnel
• Environment
• PURITY STANDARDS
  • CHEMICAL QUALITY
  • WATER QUALITY
  • GAS QUALITY
  • RECYCLING/REUSE
• Recycling/Reuse (Continued)

INDUSTRY STRUCTURE AND ITS COMPETITIVE ASPECTS

• INDUSTRY STRUCTURE AND ITS COMPETITIVE ASPECTS
• Figure 1. REGIONAL MARKET SHARE OF TOTAL WORLD SEMICONDUCTOR SALES, 2002
• Table 2. REGIONAL MARKET VALUE OF TOTAL WORLD SEMICONDUCTOR SALES, 2002
  • SEMICONDUCTOR SALES AND THE DRIVE FOR CRITICAL CHEMICALS, GASES, AND WATER
• Table 3. U.S. SHIPMENTS OF CHEMICALS, WATER, AND GASES USED IN COMPUTER MANUFACTURING COMPARED WITH SEMICONDUCTOR SHIPMENTS, THROUGH 2007 ($ MILLIONS)
  • INDUSTRY ENVIRONMENT
  • IMPORTANT STRATEGIES
  • DRIVING FORCES
  • MARKET SHARE
    • ULTRAPURE CHEMICALS MARKET LEADERS
• Leading U.S. Photomask Suppliers
• Figure 2. U.S. MARKET SHARE FOR THE MAJOR ULTRAPURE PHOTOMASKS SUPPLIERS, 2002 (%)
• Table 4. U.S. MARKET VALUE FOR THE MAJOR ULTRAPURE PHOTOMASK SUPPLIERS, 2002 ($ MILLIONS)
• Photronics
• DuPont Photomasks
• Captive Suppliers
• Leading U.S. Photoresist Suppliers
• Figure 3. U.S. MARKET SHARE OF THE MAJOR ULTRAPURE PHOTORESIST SUPPLIERS, 2002 (%)
• Table 5. U.S. MARKET VALUE OF THE MAJOR ULTRAPURE PHOTORESIST SUPPLIERS, 2002 ($ MILLIONS)
• Shipley Co.
• Arch Microelectronic Materials
• Tokyo Ohka
• AZ Electronic Materials
• Leading U.S. Wet Chemical Suppliers
• Figure 4. U.S. MARKET SHARE OF THE MAJOR ULTRAPURE WET CHEMICAL SUPPLIERS, 2002 (%)
• Table 6. U.S. MARKET VALUE FOR THE MAJOR ULTRAPURE WET CHEMICAL SUPPLIERS, 2002 ($ MILLIONS)
• Ashland Chemical
• FMC Corp.
• Solvay Interox
• Japanese Companies
• General Chemical Co.
• Mallinckrodt Baker Microelectric Materials
• DuPont Electronic Materials
• ULTRAPURE WATER MARKET LEADERS
• Figure 5. U.S. MARKET SHARE OF MAJOR ULTRAPURE WATER SUPPLIERS, 2002 (%)
• Table 7. U.S. MARKET VALUE OF MAJOR ULTRAPURE WATER SUPPLIERS, 2002 ($ MILLIONS)
• Semiconductor Manufacturers
  • Ionics Ultrapure Water
  • Glegg Water Conditioning, Inc.
  • Vivendi-U.S. Filter Corp.
• ULTRAPURE GAS MARKET LEADERS
• Ultrapure Gas Market Share
• Figure 6. U.S. MARKET SHARE OF THE MAJOR ULTRAPURE GAS SUPPLIERS, 2002 (%)
• Table 8. U.S. MARKET VALUE OF THE MAJOR ULTRAPURE GAS SUPPLIERS, 2002 ($ MILLIONS)
• Ultrapure Gas Suppliers
  • Air Products and Chemicals
  • Praxair
  • The BOC Group
  • L'Air Liquide
  • Nippon Sanyo KK

ULTRAPURE SEMICONDUCTOR MATERIALS

• Figure 7. U.S. MARKET SHARE OF THE THREE TYPES OF ULTRAPURE MATERIALS USED IN SEMICONDUCTORS, 2002 (%)
• Figure 7. (CONTINUED)
• Table 9. GROWTH OF THE U.S. MARKET FOR THE THREE TYPES OF ULTRAPURE MATERIALS USED IN SEMICONDUCTORS, THROUGH 2007 ($ MILLIONS)
  • ULTRAPURE SEMICONDUCTOR CHEMICALS
  • U.S. ULTRAPURE SEMICONDUCTOR CHEMICALS MARKET SIZE
• Figure 8. U.S. MARKET SHARE OF ULTRAPURE CHEMICALS USED IN SEMICONDUCTORS, 2002 (%)
• Table 10. GROWTH OF THE U.S. MARKET FOR ULTRAPURE CHEMICALS USED IN SEMICONDUCTORS, THROUGH 2007 ($ MILLIONS)
• PHOTOMASKS
• U.S. Photomask Market Size
• Table 11. GROWTH OF THE U.S. MARKET FOR PHOTOMASKS USED IN SEMICONDUCTORS, THROUGH 2007 ($ MILLIONS)
• Photomask Types
  • Chrome-on-Quartz Photomasks
  • Aluminate Complexes for Photomasks
• Lithographic Techniques
  • Electron/Ion-beam Lithography
  • Laser Beam Lithography
• Steppers
  • Narrow-beam Scanning
• PHOTORESISTS
• U.S. Photoresist Market Size
• Table 12. GROWTH OF THE U.S. MARKET FOR PHOTORESISTS USED IN SEMICONDUCTORS, THROUGH 2007 ($ MILLIONS)
• Photoresist Classes
  • Positive Photoresists
  • Negative Photoresists
• Deep-ultraviolet Lithography
  • Deep-ultraviolet Lithography (Continued)
• Direct Deposition and Lithography
• WET CHEMICALS
• Table 13. IMPORTANT LIQUID CHEMICALS USED IN WET ETCHING
• Table 14. IMPORTANT LIQUID CHEMICALS USED IN WET STRIPPING
• U.S. Ultrapure Wet Chemicals Market Size
• Figure 9. U.S. MARKET SHARE OF THE THREE CLASSES OF ULTRAPURE WET CHEMICALS USED IN SEMICONDUCTORS, 2002 (%)
• Table 15. GROWTH OF THE U.S. MARKET FOR THE THREE CLASSES OF ULTRAPURE WET CHEMICALS USED IN SEMICONDUCTORS, THROUGH 2007 ($ MILLIONS)
• Acids
• Figure 10. U.S. MARKET SHARE OF THE SIX ACIDSUSED IN SEMICONDUCTORS, 2002 (%)
• Table 16. GROWTH OF THE U.S. MARKET FOR THE SIX ACIDS USED IN SEMICONDUCTORS, THROUGH 2007 ($ MILLIONS)
• Sulfuric Acid
• Hydrofluoric Acid
• Hydrochloric Acid
• Phosphoric Acid
• Nitric Acid
• Acetic Acid
• Solvents
• Figure 11. U.S. MARKET SHARE FOR THE FIVE ULTRAPURE SOLVENTS USED IN SEMICONDUCTORS, 2002 (%)
• Table 17. GROWTH OF THE U.S. MARKET FOR THE FIVE ULTRAPURE SOLVENTS USED IN SEMICONDUCTORS, THROUGH 2007 ($ MILLIONS)
• Isopropyl Alcohol
• Acetone
• Methanol
• Xylene
• Other Wet Chemicals
• Table 18. GROWTH OF THE U.S. MARKET FOR OTHER WET CHEMICALS USED IN SEMICONDUCTORS, THROUGH 2007
• Hydrogen Peroxide
• Ammonium Hydroxide
• Aluminum Triisobutyl
• Phosphorus Oxychloride
• Titanium Tetrachloride
• Silicon Tetrachloride
• 1,1,1-Trichloroethane
• Trimethyl Borate
• Trimethyl Phosphate

ULTRAPURE SEMICONDUCTOR WATER

• WATER SOURCES
  • WATER-QUALITY PARAMETERS
• Conductivity
• Total Organic Carbon
• Bacterial Content
• MARKET SIZE OF U.S. ULTRAPURE WATER FOR SEMICONDUCTORS
• Figure 12. U.S. MARKET SHARE OF THE THREE ULTRAPURE WATER TREATMENT SYSTEMS USED IN SEMICONDUCTORS, 2002 (%)
• Table 19. GROWTH OF THE U.S. MARKET FOR THE THREE ULTRAPURE WATER TREATMENT SYSTEMS USED IN SEMICONDUCTORS, THROUGH 2007 ($ MILLIONS)
• REVERSE OSMOSIS SYSTEMS
• RO Osmosis Membrane Types
  • Asymmetric Membranes
  • Thin-film Composite Membranes
• RO Configuration Types
• DEIONIZATION
• Ion-exchange Systems
  • Ion-exchange Resin Classes
• Cation-exchange Resins
• Anion-exchange Resins
• Ion-exchange Resin Configurations
• Separate-bed Deionization Systems
• Mixed-bed Deionization Systems
• Nonseparating Mixed Beds
• Continuous Deionization Systems
• Electrodialysis/Electrodialysis-Reversal Systems
• FILTRATION SYSTEMS
• Ultrafiltration
  • Ultrafiltration Membranes
  • Ultrafiltration Costs

ULTRAPURE SEMICONDUCTOR GASES

• ULTRAPURE SEMICONDUCTOR GASES
• U.S. ULTRAPURE SEMICONDUCTOR GAS MARKET SIZE
• Table 20. GROWTH OF THE U.S. MARKET FOR ULTRAPURE GASES USED IN SEMICONDUCTORS, THROUGH 2007 ($ MILLIONS)
• BULK GASES
• Figure 13. U.S. MARKET SHARE OF THE FOUR BULK GASES USED IN SEMICONDUCTORS, 2002 (%)
• Table 21. GROWTH OF THE U.S. MARKET FOR THE FOUR BULK GASES USED IN SEMICONDUCTORS, THROUGH 2007 ($ MILLIONS)
• Nitrogen
• Nitrogen (Continued)
• Nitrogen (Continued)
• Hydrogen
• Argon
• Oxygen
• SPECIALTY GASES
• Figure 14. U.S. MARKET SHARE OF THE FIVE FUNCTIONS OF SPECIALTY GASES USED IN SEMICONDUCTORS, 2002 (%)
• Table 22. GROWTH OF THE MARKET FOR THE FIVE FUNCTIONS OF SPECIALTY GASES USED IN SEMICONDUCTORS, THROUGH 2007 ($ MILLIONS)
• Etchant Gases
  • Halocarbons
• Halocarbon 23
• Halocarbon 114
• Halocarbon 116
• Hydrogen Bromide
• Nitrogen Trifluoride
• Silicon Source Gases
  • Silane
  • Dichlorosilane
  • Silicon Tetrachloride
  • Trichlorosilane
• Reactant Gases
  • Ammonia
  • Boron Trichloride
  • Carbon Dioxide
  • Chlorine
  • Nitrous Oxide
  • Tungsten Hexafluoride
• Dopant Gases
  • Arsine
  • Diborane
  • Phosphine
• Other Specialty Gases
  • Helium
  • Neon
  • Krypton
  • Xenon

APPENDIX A: INDUSTRY SPECIFICATIONS FOR MAJOR CHEMICALS, GASES AND WATER USED IN SEMICONDUCTOR MANUFACTURE

• Table 23. SULFURIC ACID SPECIFICATIONS
• Table 23. (CONTINUED)
• Table 24. HYDROFLUORIC ACID SPECIFICATIONS
• Table 24. (CONTINUED)
• Table 25. HYDROCHLORIC ACID SPECIFICATIONS
• Table 25. (CONTINUED)
• Table 26. PHOSPHORIC ACID SPECIFICATIONS
• Table 26. (CONTINUED)
• Table 27. NITRIC ACID SPECIFICATIONS
• Table 27. (CONTINUED)
• Table 28. ACETIC ACID SPECIFICATIONS
• Table 28. (CONTINUED)
• Table 29. ISOPROPYL ALCOHOL SPECIFICATIONS
• Table 29. (CONTINUED)
• Table 30. ACETONE SPECIFICATIONS
• Table 31. METHANOL SPECIFICATIONS
• Table 32. XYLENE SPECIFICATIONS
• Table 33. N-BUTYL ACETATE SPECIFICATIONS
• Table 34. TECHNICAL INFORMATION FOR HYDROGEN PEROXIDE (PURE)
• Table 35. HYDROGEN PEROXIDE 30% SOLUTION SPECIFICATIONS
• Table 35. (CONTINUED)
• Table 36. AMMONIUM HYDROXIDE 29% SOLUTION SPECIFICATIONS
• Table 36. (CONTINUED)
• Table 37. TECHNICAL INFORMATION FOR ALUMINUM TRIISOBUTYL
• Table 38. TECHNICAL INFORMATION FOR PHOSPHORUS OXYCHLORIDE
• Table 39. PHOSPHORUS OXYCHLORIDE SPECIFICATIONS
• Table 40. TECHNICAL INFORMATION FOR TITANIUM TETRACHLORIDE
• Table 41. TECHNICAL INFORMATION FOR SILICON TETRACHLORIDE
• Table 42. TECHNICAL INFORMATION FOR 1,1,1-TRICHLOROETHANE
• Table 43. TECHNICAL INFORMATION FOR TRIMETHYL BORATE
• Table 44. TECHNICAL INFORMATION FOR TRIMETHYL PHOSPHATE
• Table 45. TECHNICAL INFORMATION FOR NITROGEN
• Table 46. NITROGEN SPECIFICATIONS
• Table 47. TECHNICAL INFORMATION FOR HYDROGEN
• Table 48. HYDROGEN SPECIFICATIONS
• Table 49. TECHNICAL INFORMATION FOR ARGON
• Table 50. ARGON SPECIFICATIONS
• Table 51. TECHNICAL INFORMATION FOR OXYGEN
• Table 52. OXYGEN SPECIFICATIONS
• Table 53. TECHNICAL INFORMATION FOR NITROGEN
• Table 54. NITROGEN SPECIFICATIONS
• Table 55. TECHNICAL INFORMATION FOR HYDROGEN
• Table 56. HYDROGEN SPECIFICATIONS
• Table 57. TECHNICAL INFORMATION FOR ARGON
• Table 58. ARGON SPECIFICATIONS
• Table 59. TECHNICAL INFORMATION FOR OXYGEN
• Table 60. OXYGEN SPECIFICATIONS
• Table 61. TECHNICAL INFORMATION FOR HALOCARBON 23
• Table 62. HALOCARBON 23 SPECIFICATIONS
• Table 63. TECHNICAL INFORMATION FOR HALOCARBON 114
• Table 64. HALOCARBON 114 SPECIFICATIONS
• Table 65. TECHNICAL INFORMATION FOR HALOCARBON 116
• Table 66. HALOCARBON 116 SPECIFICATIONS
• Table 67. TECHNICAL INFORMATION FOR HYDROGEN BROMIDE
• Table 68. HYDROGEN BROMIDE SPECIFICATIONS
• Table 69. TECHNICAL INFORMATION FOR NITROGEN TRIFLUORIDE
• Table 70. NITROGEN TRIFLUORIDE SPECIFICATIONS
• Table 71. TECHNICAL INFORMATION FOR SILANE
• Table 72. SILANE SPECIFICATIONS
• Table 73. TECHNICAL INFORMATION FOR DICHLOROSILANE
• Table 74. DICHLOROSILANE SPECIFICATIONS
• Table 75. TECHNICAL INFORMATION FOR SILICON TETRACHLORIDE
• Table 76. SILICON TETRACHLORIDE SPECIFICATIONS
• Table 77. TECHNICAL INFORMATION FOR TRICHLOROSILANE
• Table 78. TRICHLOROSILANE SPECIFICATIONS
• Table 79. TECHNICAL INFORMATION FOR AMMONIA
• Table 80. AMMONIA SPECIFICATIONS
• Table 81. TECHNICAL INFORMATION FOR BORON TRICHLORIDE
• Table 82. BORON TRICHLORIDE SPECIFICATIONS
• Table 83. TECHNICAL INFORMATION FOR CARBON DIOXIDE
• Table 84. CARBON DIOXIDE SPECIFICATIONS
• Table 85. TECHNICAL INFORMATION FOR CHLORINE
• Table 86. CHLORINE SPECIFICATIONS
• Table 87. TECHNICAL INFORMATION FOR NITROUS OXIDE
• Table 88. NITROUS OXIDE SPECIFICATIONS
• Table 89. TECHNICAL INFORMATION FOR TUNGSTEN HEXAFLUORIDE
• Table 90. TUNGSTEN HEXAFLUORIDE SPECIFICATIONS
• Table 91. TECHNICAL INFORMATION FOR ARSINE
• Table 92. ARSINE SPECIFICATIONS
• Table 93. TECHNICAL INFORMATION FOR DIBORANE
• Table 94. TECHNICAL INFORMATION FOR PHOSPHINE
• Table 95. PHOSPHINE SPECIFICATIONS
• Table 96. TECHNICAL INFORMATION FOR HELIUM
• Table 97. HELIUM SPECIFICATIONS
• Table 97. (CONTINUED)
• Table 98. TECHNICAL INFORMATION FOR KRYPTON
• Table 99. KRYPTON SPECIFICATIONS
• Table 100. TECHNICAL INFORMATION FOR NEON
• Table 101. NEON SPECIFICATIONS
• Table 102. TECHNICAL INFORMATION FOR XENON
• Table 103. XENON SPECIFICATIONS

APPENDIX B: DIRECTORY OF SUPPLIERS

• APPENDIX B: DIRECTORY OF SUPPLIERS
• DIRECTORY OF SUPPLIERS (CONTINUED)
• DIRECTORY OF SUPPLIERS (CONTINUED)
• DIRECTORY OF SUPPLIERS (CONTINUED)

LIST OF TABLES

• Summary Table:
  U.S. VALUE OF ULTRAPURE CHEMICALS, WATER, AND GASES USED IN SEMICONDUCTORS, THROUGH 2007 ($ MILLIONS)
• Table 1 ULTRAPURE CHEMICALS, WATER AND GASES USED IN SEMICONDUCTOR MANUFACTURING
• Table 2 REGIONAL MARKET VALUE OF TOTAL WORLD SEMICONDUCTOR SALES, 2002
• Table 3 U.S. SHIPMENTS OF CHEMICALS, WATER, AND GASES USED IN COMPUTER MANUFACTURING COMPARED WITH SEMICONDUCTOR SHIPMENTS, THROUGH 2007 ($ MILLIONS)
• Table 4 U.S. MARKET VALUE FOR THE MAJOR ULTRAPURE PHOTOMASK SUPPLIERS, 2002 ($ MILLIONS)
• Table 5 U.S. MARKET VALUE OF THE MAJOR ULTRAPURE PHOTORESIST SUPPLIERS, 2002 ($ MILLIONS)
• Table 6 U.S. MARKET VALUE FOR THE MAJOR ULTRAPURE WET CHEMICAL SUPPLIERS, 2002 ($ MILLIONS)
• Table 7 U.S. MARKET VALUE OF MAJOR ULTRAPURE WATER SUPPLIERS, 2002 ($ MILLIONS)
• Table 8 U.S. MARKET VALUE OF THE MAJOR ULTRAPURE GAS SUPPLIERS, 2002 ($ MILLIONS)
• Table 9 GROWTH OF THE U.S. MARKET FOR THE THREE TYPES OF ULTRAPURE MATERIALS USED IN SEMICONDUCTORS, THROUGH 2007 ($ MILLIONS)
• Table 10 GROWTH OF THE U.S. MARKET FOR ULTRAPURE CHEMICALS USED IN SEMICONDUCTORS, THROUGH 2007
• ($ MILLIONS)
• Table 11 GROWTH OF THE U.S. MARKET FOR PHOTOMASKS USED IN SEMICONDUCTORS, THROUGH 2007 ($ MILLIONS)
• Table 12 GROWTH OF THE U.S. MARKET FOR PHOTORESISTS USED IN SEMICONDUCTORS, THROUGH 2007 ($ MILLIONS)
• Table 13 IMPORTANT LIQUID CHEMICALS USED IN WET ETCHING
• Table 14 IMPORTANT LIQUID CHEMICALS USED IN WET STRIPPING
• Table 15 GROWTH OF THE U.S. MARKET FOR THE THREE CLASSES OF ULTRAPURE WET CHEMICALS USED IN SEMICONDUCTORS, THROUGH 2007 ($ MILLIONS)
• Table 16 GROWTH OF THE U.S. MARKET FOR THE SIX ACIDS USED IN SEMICONDUCTORS, THROUGH 2007 ($ MILLIONS)
• Table 17 GROWTH OF THE U.S. MARKET FOR THE FIVE ULTRAPURE SOLVENTS USED IN SEMICONDUCTORS, THROUGH 2007 ($ MILLIONS)
• Table 18 GROWTH OF THE U.S. MARKET FOR OTHER WET CHEMICALS USED IN SEMICONDUCTORS, THROUGH 2007
• Table 19 GROWTH OF THE U.S. MARKET FOR THE THREE ULTRAPURE WATER TREATMENT SYSTEMS USED IN SEMICONDUCTORS, THROUGH 2007 ($ MILLIONS)
• Table 20 GROWTH OF THE U.S. MARKET FOR ULTRAPURE GASES USED IN SEMICONDUCTORS, THROUGH 2007 ($ MILLIONS)
• Table 21 GROWTH OF THE U.S. MARKET FOR THE FOUR BULK GASES USED IN SEMICONDUCTORS, THROUGH 2007
• ($ MILLIONS)
• Table 22 GROWTH OF THE MARKET FOR THE FIVE FUNCTIONS OF SPECIALTY GASES USED IN SEMICONDUCTORS, THROUGH 2007 ($ MILLIONS)
• Table 23 SULFURIC ACID SPECIFICATIONS
• Table 24 HYDROFLUORIC ACID SPECIFICATIONS
• Table 25 HYDROCHLORIC ACID SPECIFICATIONS
• Table 26 PHOSPHORIC ACID SPECIFICATIONS
• Table 27 NITRIC ACID SPECIFICATIONS
• Table 28 ACETIC ACID SPECIFICATIONS
• Table 29 ISOPROPYL ALCOHOL SPECIFICATIONS
• Table 30 ACETONE SPECIFICATIONS
• Table 31 METHANOL SPECIFICATIONS
• Table 32 XYLENE SPECIFICATIONS
• Table 33 N-BUTYL ACETATE SPECIFICATIONS
• Table 34 TECHNICAL INFORMATION FOR HYDROGEN PEROXIDE (PURE)
• Table 35 HYDROGEN PEROXIDE 30% SOLUTION SPECIFICATIONS
• Table 36 AMMONIUM HYDROXIDE 29% SOLUTION SPECIFICATIONS
• Table 37 TECHNICAL INFORMATION FOR ALUMINUM TRIISOBUTYL
• Table 38 TECHNICAL INFORMATION FOR PHOSPHORUS OXYCHLORIDE
• Table 39 PHOSPHORUS OXYCHLORIDE SPECIFICATIONS
• Table 40 TECHNICAL INFORMATION FOR TITANIUM TETRACHLORIDE
• Table 41 TECHNICAL INFORMATION FOR SILICON TETRACHLORIDE
• Table 42 TECHNICAL INFORMATION FOR 1,1,1-TRICHLOROETHANE
• Table 43 TECHNICAL INFORMATION FOR TRIMETHYL BORATE
• Table 44 TECHNICAL INFORMATION FOR TRIMETHYL PHOSPHATE
• Table 45 TECHNICAL INFORMATION FOR NITROGEN
• Table 46 NITROGEN SPECIFICATIONS
• Table 47 TECHNICAL INFORMATION FOR HYDROGEN
• Table 48 HYDROGEN SPECIFICATIONS
• Table 49 TECHNICAL INFORMATION FOR ARGON
• Table 50 ARGON SPECIFICATIONS
• Table 51 TECHNICAL INFORMATION FOR OXYGEN
• Table 52 OXYGEN SPECIFICATIONS
• Table 53 TECHNICAL INFORMATION FOR NITROGEN
• Table 54 NITROGEN SPECIFICATIONS
• Table 55 TECHNICAL INFORMATION FOR HYDROGEN
• Table 56 HYDROGEN SPECIFICATIONS
• Table 57 TECHNICAL INFORMATION FOR ARGON
• Table 58 ARGON SPECIFICATIONS
• Table 59 TECHNICAL INFORMATION FOR OXYGEN
• Table 60 OXYGEN SPECIFICATIONS
• Table 61 TECHNICAL INFORMATION FOR HALOCARBON 23
• Table 62 HALOCARBON 23 SPECIFICATIONS
• Table 63 TECHNICAL INFORMATION FOR HALOCARBON 114
• Table 64 HALOCARBON 114 SPECIFICATIONS
• Table 65 TECHNICAL INFORMATION FOR HALOCARBON 116
• Table 66 HALOCARBON 116 SPECIFICATIONS
• Table 67 TECHNICAL INFORMATION FOR HYDROGEN BROMIDE
• Table 68 HYDROGEN BROMIDE SPECIFICATIONS
• Table 69 TECHNICAL INFORMATION FOR NITROGEN TRIFLUORIDE
• Table 70 NITROGEN TRIFLUORIDE SPECIFICATIONS
• Table 71 TECHNICAL INFORMATION FOR SILANE
• Table 72 SILANE SPECIFICATIONS
• Table 73 TECHNICAL INFORMATION FOR DICHLOROSILANE
• Table 74 DICHLOROSILANE SPECIFICATIONS
• Table 75 TECHNICAL INFORMATION FOR SILICON TETRACHLORIDE
• Table 76 SILICON TETRACHLORIDE SPECIFICATIONS
• Table 77 TECHNICAL INFORMATION FOR TRICHLOROSILANE
• Table 78 TRICHLOROSILANE SPECIFICATIONS
• Table 79 TECHNICAL INFORMATION FOR AMMONIA
• Table 80 AMMONIA SPECIFICATIONS
• Table 81 TECHNICAL INFORMATION FOR BORON TRICHLORIDE
• Table 82 BORON TRICHLORIDE SPECIFICATIONS
• Table 83 TECHNICAL INFORMATION FOR CARBON DIOXIDE
• Table 84 CARBON DIOXIDE SPECIFICATIONS
• Table 85 TECHNICAL INFORMATION FOR CHLORINE
• Table 86 CHLORINE SPECIFICATIONS
• Table 87 TECHNICAL INFORMATION FOR NITROUS OXIDE
• Table 88 NITROUS OXIDE SPECIFICATIONS
• Table 89 TECHNICAL INFORMATION FOR TUNGSTEN HEXAFLUORIDE
• Table 90 TUNGSTEN HEXAFLUORIDE SPECIFICATIONS
• Table 91 TECHNICAL INFORMATION FOR ARSINE
• Table 92 ARSINE SPECIFICATIONS
• Table 93 TECHNICAL INFORMATION FOR DIBORANE
• Table 94 TECHNICAL INFORMATION FOR PHOSPHINE
• Table 95 PHOSPHINE SPECIFICATIONS
• Table 96 TECHNICAL INFORMATION FOR HELIUM
• Table 97 HELIUM SPECIFICATIONS
• Table 98 TECHNICAL INFORMATION FOR KRYPTON
• Table 99 KRYPTON SPECIFICATIONS
• Table 100 TECHNICAL INFORMATION FOR NEON
• Table 101 NEON SPECIFICATIONS
• Table 102 TECHNICAL INFORMATION FOR XENON
• Table 103 XENON SPECIFICATIONS

LIST OF FIGURES

• Summary Figure:
  U.S. VALUE OF ULTRAPURE CHEMICALS, WATER, AND GASES USED IN SEMICONDUCTORS, 1992-2007($ MILLIONS)
• Figure 1 REGIONAL MARKET SHARE OF TOTAL WORLD SEMICONDUCTOR SALES, 2002
• Figure 2 U.S. MARKET SHARE FOR THE MAJOR ULTRAPURE PHOTOMASKS SUPPLIERS (%)
• Figure 3 U.S. MARKET SHARE OF THE MAJOR ULTRAPURE PHOTORESIST SUPPLIERS, 2002 (%)
• Figure 4 U.S. MARKET SHARE OF THE MAJOR ULTRAPURE WET CHEMICAL SUPPLIERS, 2002 (%)
• Figure 5 U.S. MARKET SHARE OF MAJOR ULTRAPURE WATER SUPPLIERS, 2002 (%)
• Figure 6 U.S. MARKET SHARE OF THE MAJOR ULTRAPURE GAS SUPPLIERS, 2002 (%)
• Figure 7 U.S. MARKET SHARE OF THE THREE TYPES OF ULTRAPURE MATERIALS USED IN SEMICONDUCTORS, 2002 (%)
• Figure 8 U.S. MARKET SHARE OF ULTRAPURE CHEMICALS USED IN SEMICONDUCTORS, 2002 (%)
• Figure 9 U.S. MARKET SHARE OF THE THREE CLASSES OF ULTRAPURE WET CHEMICALS USED IN SEMICONDUCTORS, 2002 (%)
• Figure 10 U.S. MARKET SHARE OF THE SIX ACIDSUSED IN SEMICONDUCTORS, 2002 (%)
• Figure 11 U.S. MARKET SHARE FOR THE FIVE ULTRAPURE SOLVENTS USED IN SEMICONDUCTORS, 2002 (%)
• Figure 12 U.S. MARKET SHARE OF THE THREE ULTRAPURE WATER TREATMENT SYSTEMS USED IN SEMICONDUCTORS, 2002 (%)
• Figure 13 U.S. MARKET SHARE OF THE FOUR BULK GASES USED IN SEMICONDUCTORS, 2002 (%)
• Figure 14 U.S. MARKET SHARE OF THE FIVE FUNCTIONS OF SPECIALTY GASES USED IN SEMICONDUCTORS, 2002 (%)