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市場調査レポート

メタルメッシュ透明導電体の市場機会:2015-2022年

Market Opportunities for Metal Meshes as Transparent Conductors, 2015-2022

発行 n-tech Research, a NanoMarkets company 商品コード 293227
出版日 ページ情報 英文 62 Pages
納期: 即日から翌営業日
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本日の銀行送金レート: 1USD=101.55円で換算しております。
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メタルメッシュ透明導電体の市場機会:2015-2022年 Market Opportunities for Metal Meshes as Transparent Conductors, 2015-2022
出版日: 2015年03月02日 ページ情報: 英文 62 Pages
概要

当レポートは、メタルメッシュ透明導電体 (メタルメッシュTC) 技術における最新の発展動向および市場機会について分析しており、主要なエンドアプリケーション部門の収益予測、メタルメッシュとその他の代替TC技術 (シルバーナノワイヤー、カーボンナノチューブ、導電性ポリマー、その他の金属酸化物) 、および従来のITO (インジウム・鈴酸化物) との比較、さらに市場の8カ年予測などをまとめ、お届け致します。

第1章 イントロダクション

  • 本書の背景
  • 本書の目的と調査範囲
  • 本書の調査方法
  • 本書の構成

第2章 透明導電体としてのメタルメッシュの進化

  • 透明導電体としてのメタルメッシュの進化
  • 銅透明導電体 vs. 銀透明導電体:チャンスはあるか?
  • メタルメッシュのメリットと課題
  • TC (透明導電体) 情勢の調査:メタルメッシュ市場規模の拡大
  • 本章の要点

第3章 メタルメッシュ透明導電体の用途および機会

  • タッチスクリーンセンサー:TC最大の機会
  • OLEDおよびTC:巨大化する可能性、しかし先が見えない市場
  • 従来型フラットパネルLCD:ITO (インジウム・鈴酸化物) の拠点
  • ソーラーパネルにおける透明導電体
  • その他のメタルメッシュTC用途
  • 本章の要点

第4章 透明導電体向けメタルメッシュのサプライヤー

  • 3M (米国)
  • Atmel (米国)
  • O-film Tech Co. (中国)
  • UniPixel (米国)
  • PolyIC (ドイツ)
  • 富士フィルム
  • 凸版印刷
  • 大日本印刷
  • 日立化成
  • Rolith (米国)
  • Zytronic (英国)
  • Visual Planet (英国)
  • Young Fast (台湾)
  • JTOUCH Corporation (台湾)
  • コニカミノルタ
  • Epigem (英国)

第5章 メタルメッシュ透明導電体市場の8カ年予測

  • 予測手法
  • 用途別
  • フラットパネルディスプレイ
  • タッチスクリーンセンサー産業
  • OLEDディスプレイ
  • OLED照明
  • E-ペーパー
  • ソーラーパネル
  • 静電気防止塗料
  • EMIシールド

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目次
Product Code: Nano-813

Metal mesh transparent conductors have come into their own in the past year, emerging as a serious alternative to widely used indium tin oxide (ITO), principally in the touch screen sensor space but also beyond that sector, where meshes are already superior in their ability to effectively spread voltage across a large panel. In fact they have been around for a long time in areas such as solar PV and digital signage, to further extending into more touch applications as well as other markets such as thin-film PV, antennas, EMI/RFI, transparent heating elements, and OLED lighting.

At the same time, metal mesh TCs still have to overcome some disadvantages. Visibility of grid lines is a no-go for most applications under consideration, as is the problem of "moiré" pattern effects-and newer iterations of metal mesh TCs seem to be solving both issues. Metal meshes also require significant and costly customization for displays. Efforts to replace silver with copper in metal meshes has proved quite challenging. These factors-plus our observation of some recent news and rumors-suggest metal meshes might not penetrate the TC market as fast as once hoped.

In this report, NanoMarkets analyzes the latest developments in metal mesh TC technology and what we see as the market opportunities, and thus revenue potential, across several key end application sectors. We also compare and contrast metal meshes against the other alternative TC technologies (silver nanowires, carbon nanotubes, conductive polymers, other metal oxides) as well as the incumbent and dominant ITO, to gauge how such market opportunities might be apportioned. The analysis in this report is based on NanoMarkets' extensive program covering the transparent conductor sector for the past decade.

Table of Contents

CHAPTER ONE: INTRODUCTION

  • 1.1. Background to this Report
    • 1.1.1. Why Metal-based TCs
    • 1.1.2. Surveying the Landscape: Where Metal Mesh TCs Fit In
    • 1.1.3. Playing the Specmanship Game
    • 1.1.4. Rumors Afoot: Trouble Brewing?
  • 1.2. Objectives and Scope of this Report
  • 1.3. Methodology of this Report
  • 1.4. Plan of this Report

CHAPTER TWO: THE EVOLUTION OF METAL MESHES AS TRANSPARENT CONDUCTORS

  • 2.1. Evolution of Metal Meshes as Transparent Conductors
    • 2.1.1. What's New in Metal Meshes
  • 2.2. Copper vs. Silver TCs: Are there Opportunities?
  • 2.3. Advantages and Challenges for Metal Mesh
    • 2.3.1. Competing on Price
    • 2.3.2. Customization and Moiré
    • 2.3.3. Visibility and Thinner Lines
  • 2.4. Surveying the TC Landscape: How Metal Meshes Size Up
    • 2.4.1. ITO: Protecting the Kingdom
    • 2.4.2. Other TCOs: Little Progress to Report
    • 2.4.3. Silver Nanowires: Metal TC Sibling Rivalry
    • 2.4.4. Carbon Nanotubes: Back on the Agenda
    • 2.4.5. Conductive Polymers: Niche Now as Then
    • 2.4.6. Fourth Generation TCs: Still Taking Shape
    • 2.4.7. Graphene: Waiting for Godot
    • 2.4.8. Metallic Films: The Perfect Material for Future Transparent Conductors?
  • 2.5. Key Points from this Chapter:

CHAPTER THREE: APPLICATIONS AND OPPORTUNITIES FOR METAL MESH TRANSPARENT CONDUCTORS

  • 3.1. Touch-Screen Sensors: The Foremost TC Opportunity
    • 3.1.1. The Rise of Pro-Cap, and a Touch-Sensor Revolution
    • 3.1.2. Reasons to Replace ITO in Pro-Cap Displays
    • 3.1.3. Analog-Resistive Touch Sensors and TCs
    • 3.1.4. Opportunities for Metal Mesh in Large Touch Panels
  • 3.2. OLEDs and TCs: A Potentially Large but Uncertain Market
    • 3.2.1. The Quest to Get Rid of ITO in OLED Displays
    • 3.2.2. Replacing ITO in OLEDs with Metal Meshes: The Good and the Bad
    • 3.2.3. OLED TVs: Great Promise for TCs, But Problems Still to Solve
    • 3.2.4. OLED Lighting: Also Seeking an Alternative TC
    • 3.2.5. OLEDs and Alternative TCs: Ifs, Ands, and Buts
  • 3.3. Conventional Flat-panel LCDs: ITO's Stronghold
    • 3.3.1. A Note on Transparent Displays and the Transparent Conductor Market
    • 3.3.2. Reality Check: Updating our Thinking on Flexible Electronics
    • 3.3.3. E-paper: A Shrinking TC Market
  • 3.4. Transparent Conductors in Solar Panels
    • 3.4.1. Thin-Film Solar PV: Any Room Among Other TCOs?
    • 3.4.2. DSC and OPV: Looking Beyond ITO, Meshes in the Running
  • 3.5. Other Applications for Metal Mesh TCs
    • 3.5.1. Anti-static Coatings
    • 3.5.2. EMI/RFI Shielding
    • 3.5.3. IR/UV Protection
    • 3.5.4. Haptics
  • 3.6. Key Points from this Chapter:

CHAPTER FOUR: SUPPLIERS OF METAL MESHES FOR TRANSPARENT CONDUCTORS

  • 4.1. 3M (U.S.)
  • 4.2. Atmel (U.S.)
  • 4.3. O-Film/Suzhou NanoGrid (China)
  • 4.4. UniPixel/Intouch (U.S.)
  • 4.5. PolyIC (Germany)
  • 4.6. Fujifilm (Japan)
  • 4.7. Toppan Touch (Japan)
  • 4.8. Dai Nippon Printing (Japan)
  • 4.9. Hitachi Chemical (Japan)
  • 4.10. Rolith (U.S.)
  • 4.11. Zytronic (U.K.)
  • 4.12. Visual Planet (U.K.)
  • 4.13. Young Fast (Taiwan)
  • 4.14. JTOUCH (Taiwan)
  • 4.15. Konica Minolta (Japan)
  • 4.16. Epigem (U.K.)

CHAPTER FIVE: EIGHT-YEAR FORECASTS FOR METAL MESH TRANSPARENT CONDUCTORS

  • 5.1. Forecasting Methodology
    • 5.1.1. Assumptions about Materials Utilization, Wastage and Yields
    • 5.1.2. Cost Assumptions
    • 5.1.3. General Economic Assumptions
  • 5.2. Eight-Year Forecast of Metal Transparent Conductor Markets by Application
  • 5.3. Eight-Year Forecasts of Metal Mesh TCs in Flat-Panel Displays
  • 5.4. Eight-Year Forecasts of Metal Mesh TCs in the Touch-Screen Sensor Industry
  • 5.5. Eight-Year Forecasts of Metal Mesh TCs in OLED Displays
  • 5.6. Eight-Year Forecasts of Metal Mesh TCs in OLED Lighting
  • 5.7. Eight-Year Forecasts of Metal Mesh TCs in E-Paper Displays
  • 5.8. Eight-Year Forecast for Metal Mesh TCs in Solar Panels
  • 5.9. Eight-Year Forecast of Metal Mesh TCs for Antistatic Coatings
  • 5.10. Eight-Year Forecast of Metal Mesh TCs for EMI Shielding
  • Acronyms and Abbreviations Used In this Report
  • About the Author

LIST OF EXHIBITS

  • Exhibit 2-1: NanoMarkets' Perspective and Expectations of Penetration of Selected Transparent Conductor Materials.
  • Exhibit 2-2: Metal Meshes and Ag Nanowires as TCs.
  • Exhibit 3-1: Why the Touch Sensor Business is Attractive for Transparent Conductor Makers
  • Exhibit 3-2: Long-Term Issues that ITO Faces in the OLED Market
  • Exhibit 5-1: Summary of Forecast of Metal Meshes by Application ($ Millions, except for final line)
  • Exhibit 5-2: Forecast of Metal Mesh TCs for Flat-Panel Displays (LCD and PDP)
  • Exhibit 5-3: Forecast of Metal Mesh TCs for Touch-Screen Displays.
  • Exhibit 5-4: Forecast of Metal Mesh TCs in OLED Displays (Excludes OLED Lighting)
  • Exhibit 5-5: Forecast of Metal Mesh TCs in OLED Lighting.
  • Exhibit 5-6: Forecast of Metal Mesh TCs in E-Paper Displays.
  • Exhibit 5-7: Forecast of Metal Mesh TCs in Thin-Film Photovoltaics.
  • Exhibit 5-8: Forecast of Metal Mesh TCs in OPV/DSC..
  • Exhibit 5-9: Forecast of Metal Mesh TCs in Antistatic Coatings.
  • Exhibit 5-10: Forecast of Metal Mesh TCs in Electromagnetic Shielding
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