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市場調查報告書
太陽能發電的透明導電體:市場機會(2011年)
Transparent Conductors in Photovoltaics: Market Opportunities 2011
| 出版商 |
NanoMarkets |
| 出版日期 |
2011年01月 |
商品編碼 |
143312 |
| 內容資訊 |
英文 72 Pages |
| 價格 |
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太陽能發電的透明導電體:市場機會(2011年) 是由出版商NanoMarkets在2011年01月所出版的。
這份英文市場調查報告書包含72 Pages 價格從美金595起跳。
本報告,分析太陽能發電的透明導電體市場,並彙整聚合物、奈米材料等的種類別動向與今後8年的預測,由下列摘要形式闡述。
報告摘要
第1章 簡介
第2章 透明導電體與對太陽能發電市場的影響
- 使用ITO的地點與理由
- 其他的TCO
- 太陽能發電用透明導電體的種類
- 透明導電聚合物
- 奈米銀與其他奈米金屬
- 奈米碳管與石墨烯
- 本章的主要重點
第3章 太陽能發電市場與透明導電體的機會
- 薄膜・有機太陽能發電的透明導電體
- CdTe
- 薄膜矽
- CIGS
- OPV以及DSC
- 何謂BIPV
- 可撓式太陽能發電與對透明導電體的影響
- 低溫・R2R處理
- 本章的主要重點
第4章 太陽能發電用透明導電體的8年預測
- 預測方式
- 太陽能發電技術的透明導電體使用預測
- 材料別透明導電體使用預測
- 預測摘要
使用於本報告的省略語
關於作者
圖表
Abstract
NanoMarkets views the opportunities for manufacturers of transparent conductor
from sales to the PV sector as highly diverse. Each type of transparent
conductor - oxides, polymers and nanomaterials - will have its own roadmap for
adoption by PV panel maker. And each type of PV - CIGS, CdTe, c-Si, etc., --
will have different requirements for transparent conductors. In this report,
NanoMarkets analyzes and quantifies these differences and identifies how
transparent conductor firms with novel products can penetrate, grow, and make
money in this market. We also examine the strategies that ITO firms will
employ as they put up a fight to retain a share for as long as they can and
what the implications of those strategies will be for all concerned.
As a highly competitive business that is increasingly sensitive to costs, the
photovoltaics industry is examining every aspect of its operations; not just
the materials it uses, but also the processes in which they are used. As PV
manufacturers lean more heavily toward lower temperatures, flexible
substrates, and roll-to-roll processing, the market TCOs which once looked so
attractive will begin to slow. We then expect that there will be another
shift in transparent conductive materials usage, one that will most probably
emphasize nanomaterials.
We also include an eight-year forecast of transparent conductor markets for
photovoltaics applications, broken out by type of conductor and type of PV.
We believe that this report will be essential reading for suppliers and
developers of transparent conductors of all types, as well as for executives
in thin-film and organic-based PV firms.
Table of Contents
Executive Summary
- E.1 How Long Can TCOs Reign in the PV World and What Comes Next?
- E.1.1 Opportunities for ITO Firms - Are There Any?
- E.1.2 Opportunities for Other TCO Firms in the PV Space
- E.2 Opportunities for Nanomaterials and Conductive Polymer Firms in the PV
Space
- E.2.1 Leading Nanomaterial/Conductive Polymer Firms Targeting the PV
Transparent Conductor Space
- E.3 How New Developments in the Transparent Conductor Space will Create
Opportunities for PV Panel Makers
- E.4 Summary of Eight-Year Forecasts of Transparent Conductors for OLEDs
Chapter One: Introduction
- 1.1 Background to this Report
- 1.1.1 The Market for Low-Cost Manufacturing
- 1.1.2 The Market for High Flexibility
- 1.1.3 Where Does ITO Fit In?
- 1.2 Objectives and Scope of this Report
- 1.3 Methodology of this Report
- 1.4 Plan of this Report
Chapter Two: Transparent Conductors and How They Impact the PV Market
- 2.1 Where ITO is Still Used and Why
- 2.2 Other TCOs: Tin Oxide and Zinc Oxide
- 2.2.1 Why Tin Oxide for PV?
- 2.2.2 Why Zinc Oxide for PV?
- 2.2.3 What About Other TCOs?
- 2.2.4 Why Would PV Ever Leave TCOs?
- 2.3 Other Types of Transparent Conductors for PV
- 2.3.1 Transparent Conductive Polymers: Are They Realistic?
- 2.3.2 Nanosilver and Other Nanometals: Coming Soon?
- 2.3.3 Carbon Nanotubes and Graphene: Future Success Story or Also-Ran?
- 2.4 Key Points Made in this Chapter
Chapter Three: Photovoltaics Markets and Opportunities for Transparent Conductors
- 3.1 Transparent Conductors in Thin-Film and Organic PV
- 3.1.1 CdTe PV
- 3.1.2 Thin-Film Silicon PV
- 3.1.3 CIGS PV
- 3.1.4 OPV and DSC
- 3.1.5 What About BIPV?
- 3.2 Flexible PV and Its Impact on Transparent Conductor Markets
- 3.2.1 How Flexible is “Flexible”: Will TCOs Work?
- 3.2.2 What the Industry Wants from a Flexible Transparent Conductor
- 3.3 Low Temperature and R2R Processing: Will They Fracture the TCOs?
- 3.3.1 The High Cost of Vacuum Deposition
- 3.3.2 Can Temperatures Be Reduced and Will It Save Money?
- 3.4 Key Points Made in this Chapter
Chapter Four: Eight-Year Forecasts for Transparent Conductors in PV
- 4.1 Forecasting Methodology
- 4.1.1 Data Sources
- 4.1.2 Scope of Forecast
- 4.1.3 Alternative Scenarios
- 4.2 Forecasts of Transparent Conductor Use by PV Technology
- 4.2.1 CdTe PV
- 4.2.2 Thin-Film Silicon PV
- 4.2.3 CIGS PV
- 4.2.4 OPV and DSC
- 4.3 Forecasts of Transparent Conductor Use by Material Type
- 4.3.1 ITO
- 4.3.2 Other TCOs
- 4.3.3 Conductive Polymers
- 4.3.4 Nanosilver-Based Films
- 4.3.5 Carbon Nanotube Films
- 4.4 Summary of Forecasts
Acronyms and Abbreviations Used In this Report
About the Author
List of Exhibits
- Exhibit E-1: Summary of Transparent Conductor Markets for Use in PV
- Exhibit 4-1: Transparent Conductor Use in CdTe PV Cells
- Exhibit 4-2: Transparent Conductor Use in Thin-Film Silicon PV Cells
- Exhibit 4-3: Transparent Conductor Use in CIGS PV Cells
- Exhibit 4-4: Transparent Conductor Use in OPV and DSC Cells
- Exhibit 4-5: ITO Use in PV Cells
- Exhibit 4-6: Other TCO Use in PV Cells
- Exhibit 4-7: Transparent Conductive Polymer Use in PV Cells
- Exhibit 4-8: Transparent Nanosilver-Based Conductor Use in PV Cells
- Exhibit 4-9: Transparent Carbon Nanotube Film Use in PV Cells
- Exhibit 4-10: Summary of Transparent Conductor Use in PV
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