有機発光ダイオード（OLED）材料市場：2008年

OLED Materials Markets-2008

発行	NanoMarkets
出版日	2008年10月	商品コード	67661
ページ情報	英文 118 Pages
価格	US$ 595 換算 ¥ 47,879 (税抜) PDF By E-mail - Advanced User License (5 users) US$ 995 換算 ¥ 80,067 (税抜) PDF By E-mail - Group Version (10 users) US$ 1,495 換算 ¥ 120,302 (税抜) PDF By E-mail - Enterprise Version (Company Wide)

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Abstract

As OLEDs finally begin to take off for both lighting and display applications, they are creating new opportunities for materials firms. This report and analyzes and quantifies these opportunities and identifies where the challenges are. The report addresses all of the segments of the OLED materials market and covers both polymers and small molecules, including materials for the new solution processable small molecule approaches to OLED fabrication. It also covers materials for all layers of the OLED from the photoactive materials themselves, through the electrodes and encapsulation materials. The report will provide detailed forecasts of materials broken out by type and application and will include strategic profiles of the leading firms who are developing and selling OLED materials of all kinds.

Key Findings:

The recent announcement by Nokia requiring its vendors to be capable of producing OLED displays is a strong indication that OLED technology is about ready for broader commercial production. GE Global Research' s success with roll-to-roll production of OLED devices indicates that OLED lighting may result in greater near term production volume than displays. Sony meanwhile has launched the world' s first OLED television. The rise of lighting and television applications, in particular, are positive for materials suppliers, because these applications require large OLEDs and hence use much more material than the small cell phone and MP3 player displays that have until recently dominated the OLED space.
OLED lighting has already exceeded the efficiency of fluorescent lamps in laboratory tests, holding out the promise of a new era of power-saving solid-state lighting. As the world becomes more energy conservation oriented and concerned about energy costs this will drive rapid growth for the OLED lighting industry and hence the demand for OLED materials. By 2015, as much as 90 percent of OLED materials by volume will be consumed by lighting applications.
Flexible substrates including a range of plastic films will rapidly gain a significant share of the market as roll-to-roll processing becomes faster and more efficient. This development will result in lighter weight devices that will open up new applications for product designers. By 2015 about one-third (by area) of all OLEDs will be fabricated on flexible substrates.
Firms capable of developing and marketing complete materials systems for OLEDs are on the rise. This means that display and lighting buyers can depend on a single supplier who will provide a matched set of materials with pre-determined characteristics. In addition, the fact that these single sources include some of the largest materials firms in the world -- such as DuPont, Merck and Sumitomo Chemical -- will help to guarantee a stable supply of OLED materials for a maturing OLED industry.
Despite this maturity there is still plenty of room for smaller innovative firms such as Novaled. As the market expands, the number of opportunities opens up to create materials tailored to specific applications and manufacturing processes. Areas where NanoMarkets sees potential are stack designs, hybrid polymer/small molecule approaches, novel forms of doping, and new types of materials for solution processed OLEDs.

Executive Summary

E.1 Introduction
E.2 Summary of Emerging Opportunities for Materials Suppliers
E.3 Implications for Equipment Makers
E.4 Implications for OLED Device Manufacturers
E.5 Key Firms Shaping the OLED Materials Market
E.6 Summary of Eight-Year Forecast of OLED Materials

Chapter One: Introduction

1.1 Background to This Report
- 1.1.1 Are We there Yet?
- 1.1.2 Heading Off in Many Directions at Once
- 1.1.3 How do We Get There?
1.2 Goal and Scope of This Report
1.3 Methodology and Information Sources for this Report
1.4 Plan of This Report

Chapter Two: OLED Technology and Materials

2.1 Introduction
- 2.1.1 Polymer and Small-Molecule OLEDs
- 2.1.2 Fluorescent vs. Phosphorescent Materials
- 2.1.3 Top Emitting vs. Bottom Emitting Designs
2.2 OLED Stack Structure
- 2.2.1 Adding Additional Layers
2.3 Impact of Stack Design on Materials
2.4 OLED Materials
- 2.4.1 Photoactive Materials (EML)
- 2.4.2 Substrates for OLEDs
- 2.4.3 Anode Materials
- 2.4.4 Hole Injection Materials (HIL)
- 2.4.5 Hole Transport Layer Materials (HTL)
- 2.4.6 Electron Blocking Materials (EBL)
- 2.4.7 Hole Blocking Materials (HBL)
- 2.4.8 Electron Transport Layer Materials (ETL)
- 2.4.9 Electron Injection Layer Materials (EIL)
- 2.4.10 Cathode Materials
- 2.4.11 Optical Layers
- 2.4.12 Encapsulation and Barrier Coating Materials
- 2.4.13 Other Materials
2.5 OLED "Inks"
- 2.5.1 Polymer Inks
- 2.5.2 Small-Molecule Inks
2.6 Key Points in this Chapter

Chapter 3: Applications and Forecasts

3.1 Forecasting Methodology
- 3.1.1 Forecasts-based on Material Content
- 3.1.2 Forecasts Based on Manufacturing and Architectural Analysis
- 3.1.3 How Much Confidence Should You Have in These Forecasts?
3.2 Analysis of OLED Materials Requirements by Application
- 3.2.1 Mobile Phones and Handheld Displays
- 3.2.2 MP3 Players
- 3.2.3 Televisions
- 3.2.4 Other OLED Displays
- 3.2.5 OLED Backlighting for LCD Displays
- 3.2.6 OLED Lighting for General Illumination
- 3.2.7 OLED Architectural and Specialized Industrial Lighting
- 3.2.8 Other OLED Lighting
3.3 Eight-year Forecast of OLED Display Materials by Materials Type
- 3.3.1 Small Molecule OLED Materials (less substrates)
- 3.3.2 Polymer OLED Materials (less substrates)
- 3.3.3 Combined OLED Materials (less substrates)
3.4 Eight-year Forecast of OLED Substrates
3.5 Summary of Eight-Year Forecasts of OLED Materials
3.6 Key Points in this Chapter

Chapter 4: Supplier Profiles

4.1 Add-Vision, Inc. (AVI)
4.2 Agfa
4.3 BASF
4.4 Cambridge Display Technologies
4.5 Chisso Petrochemical Corporation
4.6 Ciba
4.7 Corning Inc.
4.8 Dongwoo Fine-Chem
4.9 Doosan Electro Materials
4.10 Dow Corning
4.11 DuPont
4.11.1 DuPont Teijin Films
4.12 Eastman Kodak Company
4.13 e-Ray Optoelectronics Technology Co.
4.14 GE Global Research
4.15 Gracel Display Inc. (GDI)
4.16 H.C. Starck
4.17 Hodogaya Chemical
4.18 Idemitsu Kosan
4.19 Konica Minolta
4.20 LG Chem
4.21 Ludis
4.22 Luminescence Technology Corp (Lumtec)
4.23 Lumiotec
4.24 Merck
4.25 Nippon Steel Chemical Company
4.26 Novaled AG
4.27 OLED-T
4.28 OSRAM Opto Semiconductors
4.29 Polymertronics Limited
4.30 Plextronics
4.31 Samsung Cheil Industries
4.32 Sensient Imaging Technologies
4.33 Sun Fine Chem Inc.
4.34 Sumation
4.35 Universal Display Corporation (UDC)
4.36 Vitex

List of Exhibits

Exhibit E-1 Worldwide Market for OLED Materials ($ Millions)

Exhibit 3-1 Worldwide Market for OLEDs by Applications (000s of Square Meters)
Exhibit 3-2 Worldwide Market for OLEDs in Mobile Phones and Handheld Displays
Exhibit 3-3 Worldwide Market for OLEDs in MP3 Players
Exhibit 3-4 Worldwide Market for OLEDs in Televisions
Exhibit 3-5 Worldwide Market for Other OLED Displays
Exhibit 3-6 Worldwide Market for OLED Backlighting for LCD Displays
Exhibit 3-7 Worldwide OLED Lighting Market for General Illumination
Exhibit 3-8 Worldwide Market for OLED Architectural and Specialized Industrial Lighting
Exhibit 3-9 Worldwide Market for Other OLED Lighting
Exhibit 3-10 Worldwide Market for OLED Materials by Type
Exhibit 3-11 Worldwide Market for Small Molecule OLED Materials
Exhibit 3-12 Worldwide Market for Polymer OLED Materials
Exhibit 3-13 Worldwide Market for Small Molecule and Polymer OLED Materials
Exhibit 3-14 Worldwide Market for Substrate Materials
Exhibit 3-15 Summary of Eight-Year Forecasts of OLED Materials ($ Millions)