|
The carbon nanotube industry has been evolving rapidly over the past few years. Research efforts to find applications for these materials are moving into high gear, and the quantities of nanotubes produced for this research has more than doubled since 1999, along with an increase in the number of nanotube producers. Carbon nanotubes are some of the strongest materials known, which has made them attractive for applications such as advanced composites. Furthermore, nanotubes can be made with various resistivities, and have been used to construct switches and junctions. This report will examine the production processes and the industry structure of the firms producing and consuming these goods. This report also compares the markets for the various types of nanotubes (single wall and multi wall) and evaluates the potential near and longer-term applications for these materials. Market forecasts will be provided for 2001 through 2006.
|
Additional InformationOBJECTIVE AND PURPOSE OF THIS REPORT
This report focuses on carbon nanotubes ¾ their technology, production, and applications. There has been enormous interest in the commercialization of nanotubes for both near and distant applications, and several of these applications will be successful shortly.
Nanotubes, cylinders of carbon atoms with diameters ranging from less than 1 to 300 nanometers (nm), are some of the strongest, stiffest materials known. Furthermore, these materials are either conductors or semi-conductors, depending on their structure and environment. Nanotubes have some physical properties that have no counterpart in macroscopic materials.
With advances in synthetic techniques and the ability to characterize materials readily on an atomic scale, interest has been piqued in nanometer-size materials. Since nanometer-size grains, cylinders, and plates have dramatically larger surface areas compared to their conventional-size materials, the chemistry of these nano-size materials is altered compared to that of conventional materials.
Macroscopic carbon compounds, such as diamond and graphite, have been known for centuries. These two forms of carbon compounds have been used in various applications, ranging from lubricants to wear-resistant coatings. Although these materials have been available for many years, new applications of these materials are still being discovered today. It is clear that both graphite and diamond are economically important materials.
For many years, it was thought that graphite and diamond represented the only two stable forms of carbon-only compounds. Thus, it came as quite a surprise when Richard Smalley and coworkers at Rice University announced the discovery of a new form of carbon compound in 1985. These carbon compounds were called "fullerenes," or "buckyballs," after Buckminster Fuller. Buckminster Fuller is best known for developing the geodetic dome, and the new carbon compounds greatly resembled these domes, albeit at an atomic level. The first fullerenes to be characterized consisted of 60 carbon atoms arranged like a soccer ball.
Since the two known forms of carbon, diamond and graphite, have proven to be very useful materials, it was hoped that fullerenes would prove valuable as well. Unfortunately, although these compounds stirred a great deal of interest, their primary value to date has been to academic researchers, who have received innumerable grants to study these compounds. No applications to take advantage of the structures of these molecules have been developed, although there is still a great deal of research being carried out on drug delivery systems.
In the past decade, Iijima at NEC discovered a similar type of molecule, a fullerene that is cylindrical rather than spherical. These cylindrical fullerenes have a much wider range of potential applications compared to the spherical molecules, and already these compounds have been used in some limited applications.
While it is impossible to make a wire out of a sphere, cylinders are another matter. Characterization of the fullerene cylinders, soon termed "nanotubes," showed that there was a range of conductivities of these molecules. Therefore, it was theoretically possible to use nanotubes to produce wires that were orders of magnitude smaller and lighter than anything previously technologically possible. Cylinders can also be used to make fibers or construct weaves or mesh ¾ something that cannot be accomplished with spheres. Thus, nanotubes are really much more versatile than the first buckyballs, and are being studied for a much broader range of applications.
This report summarizes the status of nanotube production and technology. It also covers the applications for these nanotubes and estimates their possible future markets. Armed with this information, readers with business interests can make sound judgements regarding marketing strategies, investment decisions, or strategic plans concerning the market for nanotubes. This report has been written to be readily accessible for those readers with a business background, but accuracy concerning the technical aspects of nanotube manufacture and applications has not been sacrificed.
REASONS FOR THIS STUDY
While there has been much ballyhoo in the popular press concerning the wonders of nanotubes, it is difficult to get solid information on how much of these nanotubes are being produced and sold. Furthermore, many articles have presented wildly misleading information concerning these materials' manufacture, markets, and applications. This report offers a timely picture of trends for nanotubes that cannot be obtained from other sources.
CONTRIBUTIONS THE STUDY
This report shows the current (small) and future sizes of the nanotube markets in the U.S. and globally. Since research on nanotubes is being done worldwide, this report covers developments in all regions of the world. However, there are large sums of money being appropriated for nanotube research by Congress; therefore, the U.S. will be one of the countries at the forefront of nanotube research and development for some years to come. Readers of this report will be able to distinguish the hype concerning the uses of nanotubes from the reality of the market. A number of the potentially significant markets of nanotubes have received relatively little press, and many of the published articles concerning the uses of these materials do not provide an accurate picture. This report will also show what applications are achievable without any new breakthroughs in the production methodology of nanotubes, and what applications require nanotubes to be produced much less expensively.
SCOPE AND FORMAT
In order to generate the information necessary to construct a reasonable future market for nanotubes, it is necessary to take a hard-headed look at the potential advantages and pitfalls of these materials. However, given the novel applications of nanotubes, it can be difficult to compare them to more conventional macroscopic materials. Furthermore, nanotubes do offer the possibility of revolutionary, rather than evolutionary, developments in many product applications.
While many applications of nanotubes are clearly not going to happen in the next decade (especially the highly touted replacement of silicon in transistors in integrated circuits), this does not mean that there will be no applications of nanotubes in other markets. This report therefore focuses on the near-term potential applications of nanotubes, rather than applications requiring major technological leaps, such as micro-electromechanical (MEM) applications or other transistor applications. Therefore, this report focusses on applications of nanotube materials that are possible within the next five to 10 years.
The report is broken into six sections. First, there is a technology overview, which gives the broad details of nanotubes, along with some of their physical properties and methods of manufacture. Next, there is an extensive description of the industry, which is developing the manufacturing capability for nanotubes. Firms that are developing applications for nanotubes include automotive manufacturers, chemical firms, electronic manufacturers, display firms, and others. These firms are described in the section on company profiles. Following this section on industry structure is a brief description of the government and academic laboratories that have been doing extensive research in nanotubes. Next we have a description of nanotubes by type, followed by a description of the markets for nanotubes, including future trends. The report concludes with a brief section on the rise in nanotube patents filed over the past few years.to date.
METHODOLOGY AND SOURCES OF INFORMATION
This report is the result of three months of concerted effort by the author, but also builds on a previous report written two years ago on this topic. The primary sources of information for writing this report are interviews with several dozen peoplein industry, academia, and the government. The author also attended meetings and conferences and gained much precious insight from these sources as well. Many of the people interviewed are recognized authorities in the field and provided invaluable assistance. The author would like to thank all who took the time to offer their help with this project. Secondary sources used for this report include a number of publications by the Federal government, plus items gleaned from the Internet, corporate literature, and publications in peer-reviewed literature.
Any time an estimate for a number has been made, the underlying assumptions are discussed. Thus, if the reader chooses to interpret the raw data in a different manner, it is possible to do so. Dollar amounts are in constant 2001 dollars, and average annual growth rates (AAGRs) are calculated using standard tables.
Introduction
Objective And Purpose Of This Report
Reasons For This Study
Contributions The Study
Scope And Format
Methodology And Sources Of Information
Related Reports And Author's Credentials
Bcc On-Line Services
Internet
Summary
Summary Table:
Global Markets For Research Grade Single Wall And Multiwall Nanotube For Short Term Applications, Through 2006 ($ Millions)
Summary Figure:
Global Markets For Research Grade Single Wall And Multiwall Nanotube For Short Term Applications, 2001, 2002 And 2006 ($ Millions)
Technology Overview
What Is A Nanotube?
A Brief History Of Nanotubes
Comparison Of Carbon Compounds
Table 1. Properties Of Carbon Compounds
Diamond
Graphite
Buckyballs
Nanotubes
Table 2. Energies Of Formation Of Carbon Compounds
Single Wall And Multiwall Nanotubes
Nanotube Properties
Physical Properties Of Nanotubes
Brittleness
Ductile Elongation
Strength Of Nanotubes
How Likely Are Nanotubes To Achieve This Theoretical Strength?
Modulus Of Nanotubes
Electronic Properties Of Nanotubes
Electron Emission
Quantum Wires
Varying Conductivity
Infineon's Breakthrough
Table 3. Comparison Of Nanotubes In Via And Transistor Applications In Integrated Circuits
Applications For Nanotubes
Nanotubes In Vias
Orientation
Connections
Types Of Nanotubes
Production Methodology
Performance Requirements
Time Frame
The Use Of Nanotubes
Nanotube Production
Table 4. Comparison Of Nanotube Production Technologies
Arc Discharge Technology
Advantages Of Arc Discharge Technology
Disadvantages Of Arc Discharge Technology
Competing Reactions
Scale-Up
Batch Process
Will Arc Discharge Continue To Be Used To Produce Nanotubes?
Laser Ablation
Advantages Of Laser Ablation
Disadvantages Of Laser Ablation
Time Frame
Will Laser Ablation Continue To Be Used To Produce Nanotubes?
Pulsed Laser Vaporization (Plv)
Chemical Vapor Deposition
Advantages Of Chemical Vapor Deposition
Disadvantages Of Chemical Vapor Deposition
Gas Phase Processes
Advantages Of Gas Phase Processes
Disadvantages Of Gas Phase Processes
Nanotube Separation/Characterization
Separation
Separation (Continued)
New Separation Technology
Characterization
Transmission Electron Microscopy (Tem)
Scanning Tunnel Microscopy (Stm)
Atomic Force Microscopy (Afm)
Problems In Characterizing Nanotubes
Problems In Characterizing Nanotubes (Continued)
Challenges Facing The Growth Of The Nanotube Industry
Table 5. The Two Major Challenges Affecting The Nanotube Industry
The Synthesis Problem
The Integration Problem
The Role Of Complex Product Processing
Table 6. Top Down And Bottom Up Processing
Top Down Processing
Bottom Up Processing
Nanotube Processing
Time Frame
Time Frame (Continued)
Industry Structure
Nanotube Producers
Single Wall And Specialty Multiwall Nanotube Production
A Brief History Of Nanotube Production
The Road To Commercialization
Table 7. Smalley's Theory On The High Cost Of Nanotubes
Areas Of Concern
Limited Quantities
Limited Accessibility
Limited Commercial Relevance
Smalley's Effect On The Nanotube Industry
The Fallacy Of Price
Nanotube Production In 2002
Nanotube Production Technologies
Table 8. Producers Of Nanotubes
Table 8. (Continued)
Pricing
Arc Discharge Technology
Pricing Of Arc Discharge Nanotubes
Laser Ablation/Pulsed Laser Deposition
Chemical Vapor Deposition
Pricing Of Chemical Vapor Deposition Nanotubes
Gas Phase Processes
Future Pricing Of Gas Phase Process Nanotubes
Single Wall Nanotube Producers
Specialty Multiwall Nanotube Producers
Profitability In The Industry
Nanotube Production Strategy
Table 9. Business Strategy Of Nanotube Start-Ups
Capital Expense
Volume Requirements
Pricing Strategy
Competitive Position
Strategy Of Various Firms
Bulk Multiwall Nanotube Production
A Brief History Of Multiwall Production
A Brief History Of Multiwall Production (Continued)
Comparing Single Wall And Specialty Multiwall With Bulk Multiwall Nanotube Production
Table 10. Comparison Between Single Wall And Specialty Multiwall Nanotube And Bulk Multiwall Nanotube Production
Starting Materials
Physical Plant
Energy Costs
Process
Table 11. Comparison Between Batch And Continuous Process Nanotube Production
Labor Costs
Production Volumes
Rates Of Nanotube Production
Overall Comparison
Trends In The Industry
Table 12. Two Possible Pathways For The Nanotube Industry
Captive And Open Nanotube Production
Table 13. Captive And Open Nanotube Producers
Table 13. (Continued)
Open Producers Of Nanotubes
Capacity
The Players
The Players (Continued)
Table 14. Global Open Nanotube Production Capacity, 2000 And 2002
Research Nanotubes Order Volumes
Table 15. Typical Research Nanotube Order Volumes, 1999-2002
Captive Producers Of Nanotubes
Other Captive Production
Academic Production Facilities
Independent Production
Integrated Production
Table 16. Percentage Of Single Wall Nanotubes Produced On Open And Captive Basis For The Research Market, 1999, 2002 And 2006 (%)
Display Manufacturers
Display Manufacturers (Continued)
Table 17. Display Firms Investigating Carbon Nanotubes
What Is Required To Produce Nanotubes?
Table 18. Requirements For Entering The Field Of Nanotube Production
Table 18. (Continued)
Human Capital
Table 19. Human Capital Requirements For Expansion Of The Nanotube Industry
Integration
Synthesis
Progress
Hardware
Size Of Corporations
Will Major Firms Enter Nanotube Production?
Nanotube Consumers
Electronics Firms
Electron/Field Emission
Field Emission Displays
Other Applications Of Field Emission Devices
Medical Devices
Capacitors
Battery Manufacturers
Chemical Companies
Automotive Firms
Defense Industry
Microscope Companies
Table 20. Producers Of Afm Probe Tips (%)
Figure 1. Producers Of Afm Probe Tips (%)
Company Profiles
Advanced Technology Materials, Inc. (Atmi)
Applied Nanotechnologies
Carbolex, Inc.
Carbon Nanotechnologies, Inc.
Dupont
Electrovac Gesmbh
General Motors Research And Development
Honeywell
Hyperion Catalysis International
Ise Electronics Corporation
Lucent
Mer Corporation
Molecular Nanosystems Inc.
Motorola
Nanocyl S.A.
Nanolab Inc.
Piezomax Technologies, Inc.
Pixtech
Samsung Advanced Institute Of Technology
Si Diamond Technology, Inc. (Sidt)
Government And Academic Laboratories
Academic Laboratories
Table 21. Academic Laboratories Involved In Nanotube Research, By Region
Rice University (Tubes@Rice)
North Carolina Center For Nanoscale Materials
University Of Kentucky
Washington University
Massachusetts Institute Of Technology
Ecole Polytechnique Fédérale De Lausanne
Université De Fribourg
Université De Montpellier Ii
Michigan State University
Penn State University
Harvard University
Delft University Of Technology
University Of Oklahoma
Rensselaer Polytechnic Institute (Rpi)
Government Laboratories
Overall Funding
Table 22. Growth In Nanotechnology Funding, 2000-2003 ($ Millions)
Table 23. U.S. Government Nanotechnology Spending In Fy 2002 ($ Millions)
Table 24. Nsf Proposed Nanotechnology Spending In Fy 2003 ($ Millions)
National Renewable Energy Laboratory (Nrel)
National Aeronautics And Space Administration (Nasa)
Products
Introduction
Chemistry Of Nanotubes
Types Of Nanotubes
Characterizing Nanotubes
Characterizing Nanotubes (Continued)
General Properties Of Nanotubes
Table 25. General Properties Of Nanotubes
Strength Of Nanotubes
Modulus Of Nanotubes
The Effect Of Defects On The Modulus
Comparison Of Nanotubes With Macroscopic High Modulus Materials
Table 26. Comparison Of Nanotubes With Macroscopic Materials
Conductivity
Table 27. Comparison Of Types Of Conductive Materials
Electron Emissivity
Table 28. Comparison Of Materials Used As Emitters For Field Effect Devices
Conductivity
Degradation
Disadvantages Of Nanotubes
Types Of Nanotubes
Surface Area
Chemical Resistance
Major Barriers To Nanotube Commercialization
Table 29. Major Challenges For Nanotubes
Types Of Nanotubes
Single Wall Nanotubes
Table 30. Physical And Electronic Properties Of Single Wall Nanotubes
Conductivity As A Function Of Stereochemistry
Table 31. Classification Of Nanotubes
Table 32. Conductive Properties Of Single Wall Carbon Nanotubes, By Type
The Shape Of The Nanotube Alters Its Conductivity
Size
Multiwall Nanotubes
Diameter Of Individual Tubes
Diameters Of Multiwall Nanotubes
Alternative Multiwall Nanotubes
Tube Shape
Table 33. Physical Properties Of Multiwall Nanotubes
Resistance
Comparing Single Wall And Multiwall Nanotubes
Table 34. Comparison Between Single Wall And Multiwall Nanotubes
Processing Advantages Of Multiwall Nanotubes
Temperature
Defect As A Function Of Temperature
Table 35. Advantages And Disadvantages Of Defects In Nanotubes
Aggregation
Diameter
Table 36. Effects Of Decreased Diameter On Nanotube Properties
Electron Emission
Longer Term Applications
Semiconductor Band Gap
Quantum Wires
Summary Of The Market For Carbon Nanotubes
Table 37. Volume And Value Sales Of Research Grade Carbon Nanotubes Used In Short-Term Applications, Through 2006
Functionalized Nanotubes
The Role Of Defects In Functionalization
Table 38. Comparison Between Approaches To Functionalization
Multiwall Nanotubes
Table 39. Production And Value Of Bulk Multiwall Nanotubes, Through 2006 (Millions)
Figure 2. Production And Value Of Bulk Multiwall Nanotubes, 2001, 2002 And 2006 ($ Millions)
Market Applications
Introduction
Short-Term Applications
The High Cost Of Nanotubes
The High Cost Of Nanotubes (Continued)
Table 40. Nanotube Pricing By Application
The Research Market
The Research Market (Continued)
Table 41. Volume And Value Sales Of Research Grade Carbon Nanotubes Used In Short-Term Applications, Through 2006
Future Trends In The Research Market
Field Emission Devices
What Is A Field Emission Device?
Table 42. Applications Of Field Emission Devices
Hot Filament Technology
Cold Cathode Technology
Table 43. Comparison Of Cold Cathodes And Hot Filaments
Comparison Of Hot Filament And Cold Cathode Technologies
Overall Design
Voltage Requirements
Accuracy
Challenges For Hot Filament Technology
Excessive Temperature
Poor Longevity
High Vacuum Requirements
Challenges For Cold Cathode Technology
Table 44. Challenges Facing Cold Cathode Technology
Integration Of The Cold Cathode Into The Application
Control Of The Emission - The Hot Spot Problem
Challenges For Both Technologies
Degradation
Comparison Of Spindt Tips And Nanotubes In Cold Cathode Technology
Table 45. Comparison Of Spindt Tips And Nanotubes In Cold Cathode Technology
Production Methodology
Structure And Uniformity
Current-Carrying Capability
Amounts Of Nanotubes Required
Purified Versus Unpurified
Cold Cathode Applications
Display Applications
Display Industry Markets
Table 46. The Global Electronic Display Market, Through 2006 ($ Billions)
Types Of Flat Panel Displays
Table 47. Comparison Of Flat Panel Display Technologies
Liquid Crystal
Plasma
Light Emitting Diode (Led)
Conductive Polymer (Cp) Displays (Oled Polymer)
Oled (Small Molecule)
Field Emission Displays (Fed)
Table 48. Current Field Emission Display Market, 2002 (Thousands)
Table 49. Manufacturing Challenges Facing Field Emission Displays
Phosphor Control
Vacuum Requirements
Display Sizes
Table 50. Flat Panel Displays, By Size
Small Displays
Table 51. Global Volume And Value Of Small Flat Panel Display Market, Through 2006 (Millions)
Medium Displays
Table 52. Global Volume And Value Of Medium Flat Panel Display Market, Through 2006 (Millions)
Large Displays
Very Large Displays
Table 53. Comparison Of Current Technologies For Large Display Screens
Very Large Displays (Continued)
Table 54. Global Volume And Value Of Very Large Display Market, Through 2006
Summary Of Display Markets For Carbon Nanotubes
Table 55. Nanotube-Driven Field Emission Display Market, Through 2006
Light Sources
Conventional Light Bulb Disadvantages
Comparing Existing Technologies: Incandescent Versus Fluorescent Light Sources
Table 56. Comparison Between Light Sources
Energy Costs Per Year
Secondary Costs
Design Of A Nanotube-Driven Light Source
Advantages Of A Nanotube-Driven Light Source
Increased Efficiency
Better Performance?
Markets For Nanotube-Driven Lightsources
Table 57. Nanotube-Driven Light Sources Market, Through 2006 (Millions)
Microwave Amplifiers
Microwave Amplifiers (Continued)
Base Stations
Table 58. Nanotube-Driven Microwave Base Station Amplifier Market, Through 2006 (Millions)
Military Applications
Portable Devices
X-Ray Applications
Comparison With Conventional Imaging Equipment
Table 59. Comparison Between Conventional X-Ray Imaging And Nanotube Driven X-Ray Imaging
Advantages Of Nanotube-Driven X-Ray Devices
Industrial Applications
Medical Applications
External Imaging
Portable Applications
Internal Imaging
Treatment
Fda Approval
Table 60. Global Markets For New Nanotube Driven X-Ray Devices, Through 2006
Industrial Applications Of Nanotube-Driven Field Emission Devices
Table 61. Comparison Between Conventional And Nanotube Surge Protection Technology
X-Ray Fluorometers
Table 62. Market For Portable X-Ray Fluorometers, Through 2006
Summary Of Markets For Field Emission Devices
Table 63. Global Nanotube-Driven Field Emission Device Market, Through 2006
Microscope Probes
Atomic Force Microscopy (Afm)
Probes For Afm
Tips For Afm
Table 64. Comparison Of Conventional And Carbon Nanotube Tips For Atomic Force Microscopes
Aspect Ratio
Tip Shape
Durability
Stiffness
Applications
Table 65. U.S Markets For Afm Tips, Through 2006 (Thousands)
Polymers
Table 66. Comparison Between Static Dissipative And Conductive Polymers
Table 67. Comparison Of Filler Technology For Static Dissipative And Conductive Polymers
Table 67. (Continued)
Loadings
Ability To Adjust Conductivity
Table 68. Availability Of Multiwall Nanotube Filled Polymer
Ease Of Distribution Into A Polymer
Additional Trends
Part Performance
Sloughing
Surface Finish
Ease Of Pigmentation
Cost Of Fillers
Table 69. Comparison Of Single Wall And Multiwall Nanotubes In Filled Polymer Applications
Applications
Esd Applications
Automotive Applications
E-Paint Applications
Fuel System Applications
Summary Of Markets Of Bulk Multiwall Nanotube Filled Polymers
Table 70. Market Applications For Multiwall Nanotubes, Through 2006 (Millions)
Trends
Flame Retardant Applications
Long-Term Applications
High Surface Area Applications
New Developments In High Surface Area Applications
Defects In Nanotubes
Water Desalinators
Desalinization Theory
Drivers Of Desalinization Technology
Table 71. Global Markets For Nanotube Water Purifiers, Through 2006
Additional Desalinization Technology
Energy Storage Devices
Fuel Cells
Table 72. Comparison Of Fuel Cell Applications
Small Scale Electronic Applications
Transportation Applications
Table 73. Challenges Facing The Transportation Fuel Cell
High Cost
Fuel Choices
Motor Choices
Challenges
Heat Generation
Warm-Up Times
Infrastructure
Stationary Power Generation Applications
The Two Uses Of Nanotubes In Fuel Cells
Membrane Applications
Table 74. Requirements For A Nanotube Membrane Used In Fuel Cells
Amount Of Nanotubes Required
Table 75. Global Market For Nanotube Membrane Fuel Cells, Through 2006
Hydrogen Storage
Table 76. Requirements For Hydrogen Storage Using Nanotubes
Batteries
Capacitors
Table 77. Global Market For Nanotube Capacitors, Through 2006
Summary Of Markets For High Surface Area Applications
High Strength Fiber Applications
Wire/Rope Applications
Wire/Rope Applications (Continued)
Composite Applications
Continuous Fiber Versus Long Fiber Composites
Continuous Fiber Nanotube Composites
Table 78. Problems With Continuous Fiber Nanotube Composites
Challenges
The High Cost Of Nanotubes
Lack Of Processing Technology
Inadequate Matrix Materials
Table 79. Technological Advances Required Before Nanotubes Can Be Used In A Continuous Fiber Composite
Table 80. Global Market For Continuous Fiber Nanotube Composites, Through 2006
Discontinous Fiber Composites
The Automotive Connection
Table 81. Requirements For High Performance Discontinuous Fiber Composites
Is There Really A Performance Advantage With Nanotubes Versus Other Fibers?
Table 82. Performance Enhancement By Nanotube Fillers In Polymer Matrixes
Table 83. Market For Discontinuous Fiber Nanotube Composites, Through 2006
Longer Term Outlooks
Chemical Sensors
Table 84. Advantages And Disadvantages Of A Nanotube Chemical Sensor
Possible Applications
Markets
Actuators
Table 85. Requirements For Actuator Materials
Table 86. Comparison Of Actuator Materials
Problems With Conductive Polymers
Problems With Piezoceramics
Advantages Of Nanotubes
Macroscopic Actuator Applications
Microscopic Actuator Applications
Market For Macroscopic Actuators
Table 87. Global Macroscopic Applications Of Nanotube Actuators, Through 2006
Electronic Applications
The First Phase Of Nanotube Integration
Trends In The Semiconductor Industry
Table 88. Trends In The Chipmaking Industry
Table 89. Advantages Of Nanotubes In Vias
The Integration Issue
Electrical Conductivity
Thermal Conductivity
Chemical Stability
Thermal Stability
Smaller Diameter
Summary Of First Phase Applications Of Nanotubes In Electronics
Table 90. Global Market For Electronic Applications Of Nanotubes In Chips, Through 2006 (Millions)
The Second Phase Of Nanotube Integration
Table 91. Requirements For This Second Phase Of Nanotube Integration
Connecting Two Points
Desired Conductivity
Summary
Patents
Numbers Of Patents
Table 92. Rise In Global Patents, 1999 And 2001
Nanotube Patents By Application
Table 93. Nanotube Patents, By Application (%)
Figure 3. Nanotube Patents, By Application (%)
Table 94. The Role Of Geography In Patent Filings (%)
Figure 4. The Role Of Geography In Patent Filings (%)
List Of Tables
Summary Table:
Global Markets For Research Grade Single Wall And Multiwall Nanotube For Short Term Applications, Through 2006 ($ Millions)
Table 1 Properties Of Carbon Compounds
Table 2 Energies Of Formation Of Carbon Compounds
Table 3 Comparison Of Nanotubes In Via And Transistor Applications In Integrated Circuits
Table 4 Comparison Of Nanotube Production Technologies
Table 5 The Two Major Challenges Affecting The Nanotube Industry
Table 6 Top Down And Bottom Up Processing
Table 7 Smalley's Theory On The High Cost Of Nanotubes
Table 8 Producers Of Nanotubes
Table 9 Business Strategy Of Nanotube Start-Ups
Table 10 Comparison Between Single Wall And Specialty Multiwall Nanotube And Bulk Multiwall Nanotube Production
Table 11 Comparison Between Batch And Continuous Process Nanotube Production
Table 12 Two Possible Pathways For The Nanotube Industry
Table 13 Captive And Open Nanotube Producers
Table 14 Global Open Nanotube Production Capacity, 2000 And 2002
Table 15 Typical Research Nanotube Order Volumes, 1999-2002
Table 16 Percentage Of Single Wall Nanotubes Produced On Open And Captive Basis For The Research Market, 1999, 2002 And 2006 (%)
Table 17 Display Firms Investigating Carbon Nanotubes
Table 18 Requirements For Entering The Field Of Nanotube Production
Table 19 Human Capital Requirements For Expansion Of The Nanotube Industry
Table 20 Producers Of Afm Probe Tips (%)
Table 21 Academic Laboratories Involved In Nanotube Research, By Region
Table 22 Growth In Nanotechnology Funding, 2000-2003 ($ Millions)
Table 23 U.S. Government Nanotechnology Spending In Fy 2002 ($ Millions)
Table 24 Nsf Proposed Nanotechnology Spending In Fy 2003 ($ Millions)
Table 25 General Properties Of Nanotubes
Table 26 Comparison Of Nanotubes With Macroscopic Materials
Table 27 Comparison Of Types Of Conductive Materials
Table 28 Comparison Of Materials Used As Emitters For Field Effect Devices
Table 29 Major Challenges For Nanotubes
Table 30 Physical And Electronic Properties Of Single Wall Nanotubes
Table 31 Classification Of Nanotubes
Table 32 Conductive Properties Of Single Wall Carbon Nanotubes, By Type
Table 33 Physical Properties Of Multiwall Nanotubes
Table 34 Comparison Between Single Wall And Multiwall Nanotubes
Table 35 Advantages And Disadvantages Of Defects In Nanotubes
Table 36 Effects Of Decreased Diameter On Nanotube Properties
Table 37 Volume And Value Sales Of Research Grade Carbon Nanotubes Used In Short-Term Applications, Through 2006
Table 38 Comparison Between Approaches To Functionalization
Table 39 Production And Value Of Bulk Multiwall Nanotubes, Through 2006 (Millions)
Table 40 Nanotube Pricing By Application
Table 41 Volume And Value Sales Of Research Grade Carbon Nanotubes Used In Short-Term Applications, Through 2006
Table 42 Applications Of Field Emission Devices
Table 43 Comparison Of Cold Cathodes And Hot Filaments
Table 44 Challenges Facing Cold Cathode Technology
Table 45 Comparison Of Spindt Tips And Nanotubes In Cold Cathode Technology
Table 46 The Global Electronic Display Market, Through 2006 ($ Billions)
Table 47 Comparison Of Flat Panel Display Technologies
Table 48 Current Field Emission Display Market, 2002 (Thousands)
Table 49 Manufacturing Challenges Facing Field Emission Displays
Table 50 Flat Panel Displays, By Size
Table 51 Global Volume And Value Of Small Flat Panel Display Market, Through 2006 (Millions)
Table 52 Global Volume And Value Of Medium Flat Panel Display Market, Through 2006 (Millions)
Table 53 Comparison Of Current Technologies For Large Display Screens
Table 54 Global Volume And Value Of Very Large Display Market, Through 2006
Table 55 Nanotube-Driven Field Emission Display Market, Through 2006
Table 56 Comparison Between Light Sources
Table 57 Nanotube-Driven Light Sources Market, Through 2006 (Millions)
Table 58 Nanotube-Driven Microwave Base Station Amplifier Market, Through 2006 (Millions)
Table 59 Comparison Between Conventional X-Ray Imaging And Nanotube Driven X-Ray Imaging
Table 60 Global Markets For New Nanotube Driven X-Ray Devices, Through 2006
Table 61 Comparison Between Conventional And Nanotube Surge Protection Technology
Table 62 Market For Portable X-Ray Fluorometers, Through 2006
Table 63 Global Nanotube-Driven Field Emission Device Market, Through 2006
Table 64 Comparison Of Conventional And Carbon Nanotube Tips For Atomic Force Microscopes
Table 65 U.S Markets For Afm Tips, Through 2006 (Thousands)
Table 66 Comparison Between Static Dissipative And Conductive Polymers
Table 67 Comparison Of Filler Technology For Static Dissipative And Conductive Polymers
Table 68 Availability Of Multiwall Nanotube Filled Polymer
Table 69 Comparison Of Single Wall And Multiwall Nanotubes In Filled Polymer Applications
Table 70 Market Applications For Multiwall Nanotubes, Through 2006 (Millions)
Table 71 Global Markets For Nanotube Water Purifiers, Through 2006
Table 72 Comparison Of Fuel Cell Applications
Table 73 Challenges Facing The Transportation Fuel Cell
Table 74 Requirements For A Nanotube Membrane Used In Fuel Cells
Table 75 Global Market For Nanotube Membrane Fuel Cells, Through 2006
Table 76 Requirements For Hydrogen Storage Using Nanotubes
Table 77 Global Market For Nanotube Capacitors, Through 2006
Table 78 Problems With Continuous Fiber Nanotube Composites
Table 79 Technological Advances Required Before Nanotubes Can Be Used In A Continuous Fiber Composite
Table 80 Global Market For Continuous Fiber Nanotube Composites, Through 2006
Table 81 Requirements For High Performance Discontinuous Fiber Composites
Table 82 Performance Enhancement By Nanotube Fillers In Polymer Matrixes
Table 83 Market For Discontinuous Fiber Nanotube Composites, Through 2006
Table 84 Advantages And Disadvantages Of A Nanotube Chemical Sensor
Table 85 Requirements For Actuator Materials
Table 86 Comparison Of Actuator Materials
Table 87 Global Macroscopic Applications Of Nanotube Actuators, Through 2006
Table 88 Trends In The Chipmaking Industry
Table 89 Advantages Of Nanotubes In Vias
Table 90 Global Market For Electronic Applications Of Nanotubes In Chips, Through 2006 (Millions)
Table 91 Requirements For This Second Phase Of Nanotube Integration
Table 92 Rise In Global Patents, 1999 And 2001
Table 93 Nanotube Patents, By Application (%)
Table 94 The Role Of Geography In Patent Filings (%)
List Of Figures
Summary Figure:
Global Markets For Research Grade Single Wall And Multiwall Nanotube For Short Term Applications, 2001, 2002 And 2006 ($ Millions)
Figure 1 Producers Of Afm Probe Tips (%)
Figure 2 Production And Value Of Bulk Multiwall Nanotubes, 2001, 2002 And 2006 ($ Millions)
Figure 3 Nanotube Patents, By Application (%)
Figure 4 The Role Of Geography In Patent Filings (%)
