Description
Nanomaterials market analysis and forecast of Nano-materials for electronics developments, nanomaterial-based solar cells, RFID, displays and sensors.
Eventually, nanomaterials are likely to affect nearly every industry in every region in the world, including the least developed regions. In fact, there is considerable optimism that nanomaterials will be instrumental in addressing some of the developing world’s most pressing concerns. Forecasts are presented for nanomaterials for solar cells, displays, lighting, and RFIDs devices.
Nanomaterial Market Outlook: Solar Cells, Displays, Sensors, Lighting and RFID
TABLE OF CONTENTS
Chapter 1: Introduction
Chapter 2: Nanomaterial Properties and Fabrication
2.1. Introduction
2.2. Materials Used In Nanotechnology
2.2.1. Fullerenes
2.2.1.1. Buckyballs – Buckminsterfullerene
2.2.1.2. Buckytubes – Nanotubes
2.2.1.3. Fabrication Of Nanotubes
2.2.2. Nanoparticles
2.2.2.1. Introduction
2.2.2.2. Fabrication Of Nanoparticles
Chapter 3: Developments In Nanomaterial-Based Solar Cells
3.1. Introduction
3.2. Nanomaterials As Solar Conversion
3.2.1. Inorganic Nanocrystals
3.2.1.1. Silicon Nanoparticles
3.2.1.2. Nobel Metals
3.2.1.3. Multimetal-Dielectric Nanocomposites
3.2.2. CdSe And CdTe Nanorods
3.2.3. Quantum Dots
3.2.4. Nanocomposite – Quantum Dot Combination
3.2.5. Quantum Wells
3.2.6. Organic Polymers – Fullerenes
3.2.7. Ionic Organic Polymers
3.2.8. CIGS
3.2.9. Dye-Sensitized Solar Cells
3.3. Nanomaterials As Modified Electrodes
3.3.1. Nanowires
3.3.1.1. ZnO Nanowires
3.3.1.2. InP Nanowires
3.3.2. Carbon Nanotubes
3.3.2.1. Defected Carbon Nanotubes
3.3.2.2. Silicon Nanotubes
3.3.2.3. Titania Nanotubes
3.4. Theoretical Work
Chapter 4: Nanomaterials for Displays
4.1. Introduction
4.2. LCDs
4.3. Electrophoretic/Electrochromic Displays
4.3.1. Electrophoretic Displays
4.3.2. Electrochromic Displays
4.4. OLEDs
4.5. Backplanes
Chapter 5: Nanomaterials for Sensors
5.1. Introduction
5.2. NanoChemical Sensors
5.3. NanoBio/NanoMed Sensors
5.5. Military and Homeland Defense Applications
5.5. Quantum Dot Sensors
5.6. Others
Chapter 6: Nanomaterials for Lighting
6.1. Introduction
6.2. High-efficiency Organic LEDs (OLEDs)
6.3. Electroluminescent Devices
Chapter 7: Nanomaterials for RFIDs
7.1. Introduction
7.2. RFID Devices
7.3. Current Uses
7.4. Uses For Potential Strong Growth
Chapter 8: Nanomaterials for Semiconductors
8.1. Nanotubes For Integrated Circuits
8.2. Slurries
8.3. Lithography
8.3.1. Photoresist
8.3.2. DUV Immersion Liquid
Chapter 9: Nanomaterial Deposition Trends
9.1. Vapor Phase
9.2. Electrodeposition
9.3. Spray Pyrolysis
9.4. Laser Pyrolysis
9.5. Screen Printing
9.6. Small Nanoparticle Deposition
9.7. Slurry Spraying And Meniscus Coating Of Precursors
9.8. Ink-Jet
9.9. Dip Pen Nanolithography
Chapter 10: Analysis and Forecast of Nanomaterials for Electronics
10.1. Driving Forces
10.2. Analysis of Nanomaterial Markets for All Applications
10.3. Analysis of Nanomaterial Markets for Electronics by Material
10.3.1. Analysis of Nanomaterial Markets for Nanocomposites
10.3.2. Analysis of Nanomaterial Markets for Nanoparticles
10.3.3. Analysis of Nanomaterial Markets for Nanowires
10.3.4. Analysis of Nanomaterial Markets for Fullerenes
10.3.5. Analysis of Nanomaterial Markets for Slurries
10.3.6. Analysis of Nanomaterial Markets for Precursors
10.3.7. Analysis of Nanomaterial Markets for Catalysts
10.3.8. Analysis of Nanomaterial Markets for Coatings
10.3.9. Analysis of Nanomaterial Markets for Designer Materials
10.3.10. Analysis of Nanomaterial Markets for Engineered Substrates
10.4. Analysis of Nanomaterial Markets for Electronics by Application
10.4.1. Analysis of Nanomaterial Markets for Lighting
10.4.2. Analysis of Nanomaterial Markets for Displays
10.4.3. Analysis of Nanomaterial Markets for RFID
10.4.4. Analysis of Nanomaterial Markets for Sensors
10.4. 5. Analysis of Nanomaterial Markets for Solar Cells
10.4.6. Analysis of Nanomaterial Markets for Semiconductors
List of Figures
2.1. Surface Area Comparison Of Nanomaterials
2.2. Typical Structures Of Fullerene
2.3. Arc-Electric Discharge Fabrication Method
2.4. CVD Fabrication Method
2.5. Solutions Of Monodisperse CCSE Nanocrystals
2.6. Nanoparticles By Sol Gel Technique
2.7. Nanoparticles By Physical Vapor Synthesis
3.1. Amorphous Silicon Solar Film Diagram
3.2. CIGS Solar Film Roll-To-Roll Diagram
3.3. CdTe Solar Film Diagram
3.4. Conversion Of Light Via Plasmons
3.5. Solar Emission From Nanoparticles
3.6. Energy Levels Of CdSe Quantum Dots
3.7. Schematic Diagram Of Quantum Well Solar Cell
3.8. CIGS Module Cross Section
3.9. How Dye-Sensitized Solar Cells Work
3.10. Dye-Sensitized Solar Cells Components
3.11. Electron Transport Across Nanostructured Semiconductor Films
3.12. Electron Transport In Nanoparticle Solar Cell
3.13. Carbon Nanotubes In Organic Solar Cells
4.1. Nanoink’s Dip Pen Nanolithography Technology
4.2. Inkjet Printing Of A Plastic Transistor
4.3. Vials Of Fluorescent CdSe QDS Dispersed In Hexane
4.4. A QD-LED Device
5.1. Carbon Nanotube Biosensor
5.2. Sensors In Defense Applications
7.1. EPC RFID Tag
9.1. Vapor Phase Deposition Of Nanomaterials
9.2. Electrodeposition Of Nanomaterials
9.3. Spray Pyrolysis Deposition Of Nanomaterials
9.4. Screen Printing Of Nanomaterials
10.1. Worldwide Solar Cell Production
10.2. Nanomaterial Share By Technology – 2010 And 2015
List of Tables
4.1. Proven Inks/Substrates
10.1. A Selection Of Current And Future Applications Using Nanoparticles
10.2. NNI Budget
10.3. NNI Budget History
10.4. Nanoelectronic Applications By Industry
10.5. Worldwide Nanomaterial Markets For Electronics By Material.
10.6. Worldwide Nanomaterial Markets For Electronics By Application
10.7. Worldwide Thin Film Solar Cell Forecast