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市場調査レポート

エレクトロニクス・フォトニクス・センサー向けグラフェンの世界市場

The Global Market for Graphene in Electronics, Photonics and Sensors

発行 Future Markets, Inc. 商品コード 297931
出版日 ページ情報 英文 206 Pages
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エレクトロニクス・フォトニクス・センサー向けグラフェンの世界市場 The Global Market for Graphene in Electronics, Photonics and Sensors
出版日: 2015年08月21日 ページ情報: 英文 206 Pages
概要

グラフェンやその他の2D素材は、次世代のフレキシブル/プリンテッドエレクトロニクスやフォトニクス、各種センサー向けの最先端材料の最有力候補として挙げられています。

当レポートでは、世界のグラフェン市場の最新動向や研究開発 (R&D) 状況について分析し、グラフェンの特性や生産方法、他のナノマテリアルとの比較、今後の技術開発の方向性、市場規模の実績値と予測値、地域別および用途別 (エレクトロニクス・フォトニクス・各種センサーなど) の詳細動向、主要企業(開発/製造企業)のプロファイルなどを調査しています。

第1章 分析手法

第2章 エグゼクティブ・サマリー

第3章 イントロダクション

  • ナノマテリアルの特徴
  • 分類
  • グラフェン
    • 3Dグラフェン
    • グラフェン量子ドット
  • 特質
  • カーボンナノチューブとの比較 (コスト・生産量)
  • その他の2D素材
  • グラフェンの種類
  • 生産手法
    • 品質
    • 産業規模での生産
    • グラフェンナノ血小板 (GNP)
    • グラフェンナノリボン
    • 大面積グラフェンフィルム
    • 酸化グラフェンフレーク (GO)
    • グラフェンの生産手法と賛成・反対意見
    • 最新の合成手法
    • 企業別の合成手法

第4章 グラフェン市場の構造

第5章 規制と規格

第6章 世界各国のグラフェン業界への資金供給と支援策

  • 欧州
    • EU (欧州連合)
    • 英国
    • ドイツ
    • フランス
    • スペイン
    • デンマーク
    • スウェーデン
    • ポーランド
  • 米国
  • アジア
    • 日本
    • 中国
    • 韓国
    • シンガポール
  • ブラジル
  • アルゼンチン

第7章 グラフェンの活用分野のロードマップ

第8章 グラフェン市場全体およびエンドユーザー別市場の分析

  • 生産量 (通算16年間分)
  • グラフェン産業の動向 (過去3年間分)
  • グラフェンのメーカー・生産能力・価格
  • グラフェン関連の特許とその公開状況
  • グラフェン生産の一体化
  • エレクトロニクス・フォトニクス (電子工学/光工学)
    • 透明導電性フィルム
      • 市場の促進要因と動向
      • 市場規模および市場機会
      • 製品の特性と活用分野
      • 課題
      • 近年の製品開発の動き
    • 導電性インク
    • 集積回路 (IC)
    • メモリデバイス
    • フォトニクス
  • ポリマー複合材料
  • 航空宇宙
  • 自動車
  • バイオメディカル・医療
  • コーティング (塗料)
  • 濾過・分離
  • エネルギー
    • リチウムイオン電池 (LIB)
    • スーパーコンデンサ
    • 太陽電池
    • 燃料電池
    • LED照明・UVC (遠紫外線)
    • 石油・ガス
    • 製品・活用方法の開発企業
  • センサー
  • 3Dプリンティング
  • 接着剤
  • 潤滑剤

第9章 グラフェンメーカーおよび製品開発企業 (全148社)

第10章 グラフェンの研究センター (全25機関)

図表一覧

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目次

Graphene and other 2D materials is a prime candidate advanced material for next generation flexible and printable electronics, photonics, and sensors. This report covers recent industry and research developments and charts graphene's progress and future impact in these industries.

Market sub-sectors and applications covered include:

  • Transparent conductive films
  • Conductive inks
  • Integrated circuits and field-effect transistors
  • Memory devices
  • Conductive inks
  • Technical challenges
  • Optical modulators
  • Photodetectors
  • Gas sensors
  • Biosensors
  • Product developers

Table of Contents

1. RESEARCH METHODOLOGY

2. EXECUTIVE SUMMARY

  • 2.1. Remarkable properties
  • 2.2. Global funding
  • 2.3. Products and applications
  • 2.4. Production
  • 2.5. Market drivers and trends
    • 2.5.1. Production exceeds demand
    • 2.5.2. Market revenues remain small but are growing
    • 2.5.3. Scalability and cost
    • 2.5.4. Applications hitting the market
    • 2.5.5. Wait and see?
    • 2.5.6. Asia and US lead the race
    • 2.5.7. Competition from other materials
  • 2.6. Market and technical challenges
    • 2.6.1. Supply quality
    • 2.6.2. Cost
    • 2.6.3. Product integration
    • 2.6.4. Regulation and standards

3. INTRODUCTION

  • 3.1. Properties of nanomaterials
  • 3.2. Categorization
  • 3.3. Graphene
    • 3.3.1. 3D Graphene
    • 3.3.2. Graphene Quantum Dots
  • 3.4. Properties
  • 3.5. Comparison with carbon nanotubes
    • 3.5.1.1. Cost and production
  • 3.6. Other 2D Materials
    • 3.6.1. Phosphorene
      • 3.6.1.1. Properties
      • 3.6.1.2. Applications
      • 3.6.1.3. Recent research news
    • 3.6.2. Silicene
      • 3.6.2.1. Properties
      • 3.6.2.2. Applications
      • 3.6.2.3. Recent research news
    • 3.6.3. Molybdenum disulfide
      • 3.6.3.1. Properties
      • 3.6.3.2. Applications
      • 3.6.3.3. Recent research news
    • 3.6.4. Hexagonal boron nitride
      • 3.6.4.1. Properties
      • 3.6.4.2. Applications
      • 3.6.4.3. Recent research news
    • 3.6.5. Germanene
      • 3.6.5.1. Properties
      • 3.6.5.2. Applications
      • 3.6.5.3. Recent research news
    • 3.6.6. Graphdiyne
      • 3.6.6.1. Properties
      • 3.6.6.2. Applications
    • 3.6.7. Graphane
      • 3.6.7.1. Properties
      • 3.6.7.2. Applications
    • 3.6.8. Stanene/tinene
      • 3.6.8.1. Properties
      • 3.6.8.2. Applications
    • 3.6.9. Tungsten diselenide
      • 3.6.9.1. Properties
      • 3.6.9.2. Applications
    • 3.6.10. Rhenium disulphide
      • 3.6.10.1. Properties
      • 3.6.10.2. Applications
  • 3.7. Types of graphene
    • 3.7.1. Large area graphene films
    • 3.7.2. Graphene oxide flakes and graphene nanoplatelets
  • 3.8. Production methods
    • 3.8.1. Quality
    • 3.8.2. Industrial scale production
    • 3.8.3. Graphene nanoplatelets (GNPs)
    • 3.8.4. Graphene Nanoribbons
    • 3.8.5. Large-area graphene films
    • 3.8.6. Graphene oxide flakes (GO)
    • 3.8.7. Pros and cons of graphene production methods
      • 3.8.7.1. Chemical Vapor Deposition (CVD)
      • 3.8.7.2. Exfoliation method
      • 3.8.7.3. Epitaxial growth method
      • 3.8.7.4. Wet chemistry method
      • 3.8.7.5. Micromechanical cleavage method
      • 3.8.7.6. Green reduction of graphene oxide
      • 3.8.7.7. Plasma
    • 3.8.8. Recent synthesis methods
      • 3.8.8.1. Ben-Gurion University of the Negev (BGU) and University of Western Australia
      • 3.8.8.2. Graphene Frontiers
      • 3.8.8.3. MIT and the University of Michigan
      • 3.8.8.4. Oak Ridge National Laboratory
      • 3.8.8.5. University of Florida and Donghua University
      • 3.8.8.6. Ulsan National Institute of Science and Technology (UNIST) and Case Western Reserve University
      • 3.8.8.7. Trinity College Dublin
      • 3.8.8.8. Sungkyunkwan University and Samsung Advanced Institute of Technology (SAIT)
      • 3.8.8.9. Korea Institute of Science and Technology (KIST), Chonbuk National University and KRICT
      • 3.8.8.10. NanoXplore
      • 3.8.8.11. Carbon Sciences Inc.
      • 3.8.8.12. California Institute of Technology
      • 3.8.8.13. Shanghai Institute of Microsystem and Information Technology
      • 3.8.8.14. Oxford University
    • 3.8.9. Synthesis methods by company

4. GRAPHENE MARKET STRUCTURE

5. REGULATIONS AND STANDARDS

  • 5.1. Standards
  • 5.2. Regulation

6. GLOBAL GRAPHENE GOVERNMENT FUNDING AND INITIATIVES

  • 6.1. Europe
    • 6.1.1. European Union (EU)
    • 6.1.2. The United Kingdom
    • 6.1.3. Germany
    • 6.1.4. France
    • 6.1.5. Spain
    • 6.1.6. Denmark
    • 6.1.7. Sweden
    • 6.1.8. Poland
  • 6.2. United States
  • 6.3. Asia
    • 6.3.1. Japan
    • 6.3.2. China
    • 6.3.3. South Korea
    • 6.3.4. Singapore
  • 6.4. Brazil
  • 6.5. Argentina

7. GRAPHENE APPLICATIONS ROADMAP

8. GRAPHENE END USER MARKET SEGMENT ANALYSIS

  • 8.1. Production volumes 2010-2025
  • 8.2. Graphene industry news 2013-2015
  • 8.3. Producers, production capacity and prices
  • 8.4. Graphene patents & publications
    • 8.4.1. Fabrication processes
    • 8.4.2. Academia
    • 8.4.3. Regional leaders
  • 8.5. Graphene product integration
    • 8.5.1. Carbon nanomaterials
    • 8.5.2. Graphene in the supply chain
    • 8.5.3. Dispersion
    • 8.5.4. Requirements
    • 8.5.5. Production
    • 8.5.6. Commercialization
  • 8.6. ELECTRONICS AND PHOTONICS
    • 8.6.1. Transparent conductive films
      • 8.6.1.1. Market drivers and trends
      • 8.6.1.2. Market size and opportunity
      • 8.6.1.3. Properties and applications
      • 8.6.1.4. Challenges
      • 8.6.1.5. Graphene transparent conductors developments, 2013-2015
    • 8.6.2. Conductive inks
      • 8.6.2.1. Market drivers and trends
      • 8.6.2.2. Market size and opportunity
      • 8.6.2.3. Properties and applications
      • 8.6.2.4. Graphene conductive inks developments, 2013-2015
    • 8.6.3. Integrated circuits
      • 8.6.3.1. Market drivers and trends
      • 8.6.3.2. Market size and opportunity
      • 8.6.3.3. Properties and applications
      • 8.6.3.4. Challenges
      • 8.6.3.5. Graphene integrated circuits developments, 2013-2015
    • 8.6.4. Memory devices
      • 8.6.4.1. Market drivers and trends
      • 8.6.4.2. Market size and opportunity
      • 8.6.4.3. Properties and applications
      • 8.6.4.4. Graphene memory devices developments, 2013-2015
    • 8.6.5. Photonics
      • 8.6.5.1. Optical modulators
      • 8.6.5.2. Photodetectors
      • 8.6.5.3. Plasmonics
      • 8.6.5.4. Challenges
      • 8.6.5.5. Graphene photonics developments, 2013-2015
      • 8.6.5.6. Product and application developers
  • 8.7. POLYMER COMPOSITES
    • 8.7.1. Market drivers and trends
      • 8.7.1.1. Improved performance
      • 8.7.1.2. Multi-functionality
    • 8.7.2. Market size and opportunity
    • 8.7.3. Properties and applications
      • 8.7.3.1. Barrier packaging
      • 8.7.3.2. Electrostatic discharge (ESD) and electromagnetic interference (EMI) shielding
      • 8.7.3.3. Wind turbines
    • 8.7.4. Challenges
    • 8.7.5. Graphene polymer composites developments, 2013-2015
    • 8.7.6. Product and application developers
  • 8.8. AEROSPACE
    • 8.8.1. Market drivers and trends
      • 8.8.1.1. Safety
      • 8.8.1.2. Reduced fuel consumption and costs
      • 8.8.1.3. Increased durability
      • 8.8.1.4. Multi-functionality
      • 8.8.1.5. Need for new de-icing solutions
    • 8.8.2. Market size and opportunity
    • 8.8.3. Properties and applications
      • 8.8.3.1. Composites
      • 8.8.3.2. Coatings
    • 8.8.4. Graphene aerospace developments, 2013-2015
    • 8.8.5. Product and application developers
  • 8.9. AUTOMOTIVE
    • 8.9.1. Market drivers and trends
      • 8.9.1.1. Environmental
      • 8.9.1.2. Safety
      • 8.9.1.3. Lightweighting
      • 8.9.1.4. Cost
    • 8.9.2. Market size and opportunity
    • 8.9.3. Properties and applications
    • 8.9.4. Products and product developers
  • 8.10. BIOMEDICAL & HEALTHCARE
    • 8.10.1. Market drivers and trends
      • 8.10.1.1. Improved drug delivery
      • 8.10.1.2. Biocompatibility
      • 8.10.1.3. Anti-biotic resistance
      • 8.10.1.4. Growth in advanced woundcare market
    • 8.10.2. Market size and opportunity
    • 8.10.3. Properties and applications
      • 8.10.3.1. Drug delivery
      • 8.10.3.2. Gene delivery
      • 8.10.3.3. Photodynamic Therapy
      • 8.10.3.4. Wound dressings
      • 8.10.3.5. Medical devices
      • 8.10.3.6. Biosensors
      • 8.10.3.7. Medical imaging
      • 8.10.3.8. Dental
      • 8.10.3.9. Tissue engineering
    • 8.10.4. Challenges
    • 8.10.5. Graphene medical and healthcare developments, 2013-2015
    • 8.10.6. Product and application developers
  • 8.11. COATINGS
    • 8.11.1. Market drivers and trends
      • 8.11.1.1. Sustainability and regulation
      • 8.11.1.2. Cost of corrosion
      • 8.11.1.3. Improved hygiene
      • 8.11.1.4. Cost of weather-related damage
    • 8.11.2. Market size and opportunity
    • 8.11.3. Properties and applications
      • 8.11.3.1. Anti-corrosion coatings
      • 8.11.3.2. Anti-microbial
      • 8.11.3.3. Anti-icing
      • 8.11.3.4. Barrier coatings
      • 8.11.3.5. Heat protection
      • 8.11.3.6. Smart windows
    • 8.11.4. Graphene coatings developments, 2013-2015
    • 8.11.5. Products and application developers
  • 8.12. FILTRATION AND SEPARATION
    • 8.12.1. Market drivers and trends
      • 8.12.1.1. Water shortage and population growth
      • 8.12.1.2. Contamination
      • 8.12.1.3. Cost
    • 8.12.2. Market size and opportunity
    • 8.12.3. Properties and applications
      • 8.12.3.1. Water filtration
      • 8.12.3.2. Gas separation
      • 8.12.3.3. Photocatalytic absorbents
    • 8.12.4. Graphene filtration developments, 2013-2015
    • 8.12.5. Product and application developers
  • 8.13. ENERGY
    • 8.13.1. Lithium-ion batteries (LIB)
      • 8.13.1.1. Market drivers and trends
      • 8.13.1.2. Market size and opportunity
      • 8.13.1.3. Properties and applications
      • 8.13.1.4. Graphene Li-ion battery developments 2013-2015
    • 8.13.2. Supercapacitors
      • 8.13.2.1. Market drivers and trends
      • 8.13.2.2. Market size and opportunity
      • 8.13.2.3. Properties and applications
      • 8.13.2.4. Challenges
      • 8.13.2.5. Graphene supercapacitors developments, 2013-2015
    • 8.13.3. Photovoltaics
      • 8.13.3.1. Market drivers and trends
      • 8.13.3.2. Market size and opportunity
      • 8.13.3.3. Properties and applications
      • 8.13.3.4. Graphene photovoltaics developments, 2013-2015
    • 8.13.4. Fuel cells
      • 8.13.4.1. Market drivers and trends
      • 8.13.4.2. Market size and opportunity
      • 8.13.4.3. Properties and applications
      • 8.13.4.4. Challenges
      • 8.13.4.5. Graphene fuel cell developments, 2013-2015
    • 8.13.5. LED Lighting and UVC
      • 8.13.5.1. Market drivers and trends
      • 8.13.5.2. Market size
      • 8.13.5.3. Properties and applications
      • 8.13.5.4. Graphene LED developments, 2013-2015
    • 8.13.6. Oil and gas
      • 8.13.6.1. Market drivers and trends
      • 8.13.6.2. Market size and opportunity
      • 8.13.6.3. Properties and applications
    • 8.13.7. Product and application developers
  • 8.14. SENSORS
    • 8.14.1. Market drivers and trends
      • 8.14.1.1. Increased power and performance with reduced cost
      • 8.14.1.2. Enhanced sensitivity
      • 8.14.1.3. Replacing silver electrodes
      • 8.14.1.4. Growth of home diagnostics and point of care market
      • 8.14.1.5. Improved thermal stability
      • 8.14.1.6. Environmental conditions
    • 8.14.2. Market size and opportunity
    • 8.14.3. Graphene properties and applications
      • 8.14.3.1. Infrared (IR) sensors
      • 8.14.3.2. Gas and chemicals sensors
      • 8.14.3.3. Pressure sensors
      • 8.14.3.4. Biosensors
      • 8.14.3.5. Optical sensors
      • 8.14.3.6. Humidity sensors
      • 8.14.3.7. Acoustic sensors
      • 8.14.3.8. Wireless sensors
    • 8.14.4. Challenges
    • 8.14.5. Graphene sensors developments, 2013-2015
    • 8.14.6. Product and application developers
  • 8.15. 3D PRINTING
    • 8.15.1. Market trends and drivers
      • 8.15.1.1. Improved materials at lower cost
    • 8.15.2. Market size and opportunity
    • 8.15.3. Properties and applications
    • 8.15.4. Challenges
    • 8.15.5. Graphene 3D printing developments, 2013-2015
    • 8.15.6. Products and product developers
  • 8.16. ADHESIVES
    • 8.16.1. Market drivers and trends
      • 8.16.1.1. Thermal management in electronics
      • 8.16.1.2. Environmental sustainability
      • 8.16.1.3. Properties and applications
    • 8.16.2. Market size and opportunity
    • 8.16.3. Products and product developers
  • 8.17. LUBRICANTS
    • 8.17.1. Market drivers and trends
      • 8.17.1.1. Cost effective alternatives
      • 8.17.1.2. Need for higher-performing lubricants for fuel efficiency
      • 8.17.1.3. Environmental concerns
    • 8.17.2. Properties and applications
    • 8.17.3. Market size and opportunity
    • 8.17.4. Products and product developers

9. GRAPHENE PRODUCERS AND PRODUCT DEVELOPERS

  • 9.1. Producers and types of graphene produced matrix
  • 9.2. Graphene industrial collaborations
  • 9.3. 2D CARBON GRAPHENE MATERIAL CO., LTD.
  • 9.4. 2-DTECH LIMITED
  • 9.5. 3D GRAPHTECH INDUSTRIES
  • 9.6. ABALONYX AS
  • 9.7. ACS MATERIALS LLC
  • 9.8. ADVANCED GRAPHENE PRODUCTS
  • 9.9. ADVANCED MICRO DEVICES, INC.
  • 9.10. ADVEN SOLUTIONS, INC.
  • 9.11. AD-NANO TECHNOLOGIES
  • 9.12. AGAR SCIENTIFIC
  • 9.13. AIXTRON SE
  • 9.14. AMERICAN GRAPHITE TECHNOLOGIES
  • 9.15. AMO GMBH
  • 9.16. ANDERLAB TECHNOLOGIES
  • 9.17. ANEEVE NANOTECHNOLOGIES LLC
  • 9.18. ANGSTRON MATERIALS LLC
  • 9.19. APEX GRAPHENE LLC
  • 9.20. APPLIED GRAPHENE MATERIALS PLC
  • 9.21. APPLIED NANOLAYERS BV
  • 9.22. AR BROWN CO.LTD.
  • 9.23. ARCHIMEDES POLYMER TECHNOLOGIES
  • 9.24. ARVIA TECHNOLOGY
  • 9.25. ASBURY CARBONS
  • 9.26. AVANZARE INNOVACION TECNOLOGICA S.L.
  • 9.27. BASF AG
  • 9.28. BGT MATERIALS LIMTED
  • 9.29. BIOPHARMA CHEMICALS
  • 9.30. BLUEVINE GRAPHENE INDUSTRIES, INC.
  • 9.31. BST NANO CARBON LLC
  • 9.32. BTR NEW ENERGY MATERIALS INC.
  • 9.33. CALIFORNIA LITHIUM BATTERY, INC.
  • 9.34. CALEVIA, INC.
  • 9.35. CAMBRIDGE NANOSYSTEMS
  • 9.36. CARBON NANO-MATERIAL TECHNOLOGY CO., LTD.
  • 9.37. CARBON SCIENCES, INC.
  • 9.38. CHINA CARBON GRAPHITE GROUP
  • 9.39. CHONGQING MOXI SCIENCE AND TECHNOLOGY CO., LTD.
  • 9.40. CRAYONANO AS
  • 9.41. CVD EQUIPMENT CORPORATION
  • 9.42. DANUBIA NANOTECH S.R.O.
  • 9.43. DEYANG CARBONENE TECHNOLOGY
  • 9.44. DIRECTA PLUS SPA
  • 9.45. ENANOTEC
  • 9.46. EPL COMPOSITE SOLUTIONS LTD.
  • 9.47. FLEXENABLE LTD
  • 9.48. FLEXTRAPOWER
  • 9.49. FOCUS GRAPHITE INC.
  • 9.50. FUJITSU LABORATORIES
  • 9.51. GARMOR, INC.
  • 9.52. GNANOMAT S.L.
  • 9.53. GRAFEN CHEMICAL INDUSTRIES CP.
  • 9.54. GRAFENTEK
  • 9.55. GRAFTECH INTERNATIONAL
  • 9.56. GRAFOID, INC.
  • 9.57. GRANPH NANOTEC
  • 9.58. GRAPHENANO S.L.
  • 9.59. GRAPHENDO LTD.
  • 9.60. GRAPHENEX UK LTD.
  • 9.61. GRAPHENE 3D LAB INC.
  • 9.62. GRAPHENE ESD CORPORATION
  • 9.63. GRAPHENE FRONTIERS
  • 9.64. GRAPHENE INDUSTRIES LTD.
  • 9.65. GRAPHENE LEADERS CANADA
  • 9.66. GRAPHENE NANOCHEM PLC
  • 9.67. GRAPHENE PLATFORM
  • 9.68. GRAPHENE SENSORS, INC.
  • 9.69. GRAPHENE SEMICONDUCTOR SERVICES PVT.LTD.
  • 9.70. GRAPHENE SQUARE
  • 9.71. GRAPHENE TECHNOLOGIES
  • 9.72. GRAPHENETECH
  • 9.73. GRAPHENEA NANOMATERIALS
  • 9.74. GRAPHENHEX
  • 9.75. GRAPHENSIC AB
  • 9.76. GRAPHITE ZERO PTE. LTD.
  • 9.77. GRAPHOS
  • 9.78. GROLLTREX
  • 9.79. GROUP NANOXPLORE INC.
  • 9.80. HANGZHOU GELANFENG NANOTECHNOLOGY
  • 9.81. HANWHA CHEMICAL
  • 9.82. HARBIN MULAN
  • 9.83. HARPER INTERNATIONAL CORP.
  • 9.84. HAYDALE LIMITED
  • 9.85. HQ GRAPHENE
  • 9.86. HRL LABORATORIES, LLC
  • 9.87. IBM CORPORATION
  • 9.88. IEDISA
  • 9.89. IMAGINE INTELLIGENT MATERIALS PTY LIMITED
  • 9.90. INCUBATION ALLIANCE INC.
  • 9.91. INNOPHENE
  • 9.92. INTEL CORPORATION
  • 9.93. JIANGSU YUEDA NEW MATERIAL TECHNOLOGY CO., LTD
  • 9.94. JINAN MOXI NEW MATERIAL TECHNOLOGY CO., LTD
  • 9.95. JINING LEADERNANO TECH LLC
  • 9.96. LASLUMIN LLC
  • 9.97. MEIJO NANO CARBON
  • 9.98. MERCK PERFORMANCE MATERIALS
  • 9.99. NANJING SCF NANOTECH, LTD.
  • 9.100. NANO CARBON SP. Z.O.O.
  • 9.101. NANOGRAFEN
  • 9.102. NANOGRAFI NANOTECHNOLOGY
  • 9.103. NANOINNOVA TECHNOLOGIES SL
  • 9.104. NANOINTEGRIS
  • 9.105. NANOSPERSE LLC
  • 9.106. NANOSTRUCTURED & AMORPHOUS MATERIALS, INC.
  • 9.107. NANOTECH BIOMACHINES, INC.
  • 9.108. NATIONAL NANOMATERIALS
  • 9.109. NINGBO MORSH TECHNOLOGY CO., LTD.
  • 9.110. NOKIA
  • 9.111. OVATION POLYMERS
  • 9.112. PERPETUUS ADVANCED MATERIALS PLC
  • 9.113. PLANARTECH
  • 9.114. POSCO
  • 9.115. POWERBOOSTER TECHNOLOGY
  • 9.116. QUANTUM SEED LLC
  • 9.117. QINGDAO HUAGAO ENERGY TECHNOLOGY CO., LTD.
  • 9.118. R-NANO
  • 9.119. SAMSUNG ELECTRONICS CO., LTD.
  • 9.120. SANDISK CORPORATION
  • 9.121. SHANGHAI SIMBATT ENERGY TECHNOLOGY CO., LTD.
  • 9.122. SINOCARBON MATERIALS TECHNOLOGY CO., LTD.
  • 9.123. SINODE SYSTEMS
  • 9.124. THE SIXTH ELEMENT MATERIALS TECHNOLOGY CO. LTD.
  • 9.125. SER GRAPHITECH
  • 9.126. SKELETON TECHNOLOGIES
  • 9.127. SOLAN CORP
  • 9.128. SUPERC TECHNOLOGY LTD.
  • 9.129. STREM CHEMICALS
  • 9.130. SUNVAULT ENERGY INC.
  • 9.131. TAIWAN CARBON NANOTUBE TECHNOLOGY
  • 9.132. TAIZHOU SUNANO NEW ENERGY CORPORATION
  • 9.133. TALGA RESOURCES
  • 9.134. TEXAS INSTRUMENTS, INC.
  • 9.135. THERAGNOSTIC TECHNOLOGIES, INC.
  • 9.136. THOMAS SWAN & CO. LTD.
  • 9.137. TIANJIN PULAN NANO TECHNOLOGIES LTD
  • 9.138. TRUE 2 MATERIALS PTE. LTD.
  • 9.139. UGENT TECH SDN BHD
  • 9.140. UNIVERSITY OF EXETER
  • 9.141. VALENCE INDUSTRIES LIMITED
  • 9.142. VORBECK MATERIALS CORPORATION
  • 9.143. WAVVE STREAM
  • 9.144. WUXI GRAPHENE FILM CO., LTD
  • 9.145. XF NANO
  • 9.146. XG SCIENCES
  • 9.147. XIAMEN KNANO
  • 9.148. XOLVE, INC.
  • 9.149. XP NANO MATERIAL CO. LTD.
  • 9.150. ZAPGOCHARGER LTD.

10. GRAPHENE RESEARCH CENTRES

  • 10.1. Brookhaven Center for Functional Nanomaterials
  • 10.2. CEMES, Toulouse
  • 10.3. Chinese Academy of Sciences, Chongqing Green Smart Technology Research Institute (Chongqing Research Institute)
  • 10.4. Chinese Academy of Sciences, Institute of Metal Research
  • 10.5. CRANN (the Centre for Research on Adaptive Nanostructures and Nanodevices), Trinity College Dublin
  • 10.6. Cornell University, Department of Chemistry and Chemical Biology
  • 10.7. Georgia Tech, Epitaxial Graphene Lab
  • 10.8. Institute of Electronic Materials Technology (ITME)
  • 10.9. Massachusetts Institute of Technology (MIT)
  • 10.10. Michigan State University
  • 10.11. Monash University
  • 10.12. National University of Singapore
  • 10.13. Princeton University
  • 10.14. Rensselaer Polytechnic Institute
  • 10.15. Rutgers University
  • 10.16. Stanford University
  • 10.17. Sungkyunkwan University
  • 10.18. Technical University of Denmark, DTU Nanotech
  • 10.19. University of California Los Angeles (UCLA)
  • 10.20. University of Cambridge
  • 10.21. University of Exeter
  • 10.22. University of Manchester
  • 10.23. University of Pennsylvania
  • 10.24. University of Texas, Austin
  • 10.25. University of Wisconsin-Milwaukee

TABLES AND FIGURES

  • Figure 1: Global government funding for graphene.
  • Table 1: Graphene target markets-Applications, stage of commercialization and potential addressable market size.
  • Table 2: Graphene production plants worldwide, by country, and production capacity.
  • Table 3: Global production of graphene, 2010-2025 in tons/year. Base year for projections is 2014.
  • Figure 2: Global market for graphene 2010-2025 in tons/year.
  • Table 4: Market penetration and volume estimates (tons) for graphene in key markets.
  • Table 5: Graphene types and cost per kg (Source: Haydale).
  • Table 6: Categorization of nanomaterials.
  • Figure 3: Graphene layer structure schematic.
  • Figure 4: Graphite and graphene.
  • Figure 5: Graphene and its descendants.
  • Table 7: Properties of graphene.
  • Figure 6: Graphene can be rolled up into a carbon nanotube, wrapped into a fullerene, and stacked into graphite.
  • Table 8: Comparative properties of carbon materials.
  • Table 9: Comparative properties of graphene with nanoclays and carbon nanotubes.
  • Figure 7: Phosphorene structure.
  • Table 10: Recent phosphorene research news.
  • Figure 8: Silicene structure (Source: Nature).
  • Table 11: Recent silicene research news.
  • Figure 9: Structure of 2D molybdenum disulfide.
  • Figure 10: Atomic force microscopy image of a representative MoS2 thin-film transistor.
  • Figure 11: Schematic of the molybdenum disulfide (MoS2) thin-film sensor with the deposited molecules that create additional charge.
  • Table 12: Recent Molybdenum disulfide research news.
  • Figure 12: Structure of hexagonal boron nitride.
  • Table 13: Recent hexagonal boron nitride research news.
  • Figure 13: Schematic of germanane.
  • Table 14: Recent germanane research news.
  • Figure 14: Graphdiyne structure.
  • Figure 15: Schematic of Graphane crystal.
  • Figure 16: Crystal structure for stanene.
  • Figure 17: Schematic of tungsten diselenide.
  • Figure 18: Schematic of a monolayer of rhenium disulphide.
  • Table 15: Comparative analysis of graphene and other 2-D nanomaterials.
  • Table 16: Large area graphene films-Markets, applications and current global market.
  • Table 17: Graphene oxide flakes/graphene nanoplatelets-Markets, applications and current global market.
  • Table 18: Main production methods for graphene.
  • Figure 19: Graphene synthesis methods.
  • Table 19: Recent graphene synthesis methods.
  • Table 20: Graphene synthesis methods, by company.
  • Table 21: Graphene market structure.
  • Table 22: Global government funding for graphene, total.
  • Figure 20: Global government funding for graphene.
  • Table 23: Graphene applications roadmap-Stage of commercialization, from basic concept to mass production.
  • Table 24: Global production of graphene, 2010-2025 in tons/year. Base year for projections is 2014.
  • Figure 21: Global production of graphene, 2010-2025 in tons/year. Base year for projections is 2014.
  • Table 25: Market penetration and volume estimates (tons) for graphene in key applications.
  • Table 26: Graphene producers and production capacity (Current and projected), prices and target markets.
  • Table 27: Published patent publications for graphene, 2004-2014.
  • Figure 22: Published patent publications for graphene, 2004-2014.
  • Table 28: Leading graphene patentees.
  • Table 29: Industrial graphene patents in 2014.
  • Figure 23: CamGraph powder from Cambridge Nanosystems.
  • Figure 24: Graphenstone paint.
  • Table 30: Graphene in the electronics and photonics market-applications, stage of commercialization and addressable market size.
  • Table 31: Comparison of ITO replacements.
  • Figure 25: A large transparent conductive graphene film.
  • Figure 26: Flexible transistor sheet.
  • Figure 27: The transmittance of glass/ITO, glass/ITO/four organic layers, and glass/ITO/four organic layers/4-layer graphene.
  • Table 32: Graphene transparent conductors developments, 2013-2015.
  • Table 33: Comparative properties of conductive inks.
  • Figure 28: Vorbeck Materials conductive ink products (Image credit: Vorbeck Materials).
  • Figure 29: Graphene printed antenna.
  • Figure 30: Graphene ink product.
  • Table 34: Graphene conductive inks developments, 2013-2015.
  • Figure 31: Schematic cross-section of a graphene base transistor and a graphene field-effect transistor.
  • Figure 32: Graphene IC in wafer tester.
  • Figure 33: Graphene barristor.
  • Table 35: Graphene integrated circuits developments, 2013-2015.
  • Figure 34: A schematic diagram for the mechanism of the resistive switching in metal/GO/Pt.
  • Table 36: Graphene memory devices developments, 2013-2015.
  • Table 37: Graphene properties relevant to application in optical modulators.
  • Table 38: Graphene product and application developers in the electronics industry.
  • Table 39: Dispersion of graphene in polymers.
  • Table 40: Graphene in the polymer composites market-applications, stage of commercialization and addressable market size.
  • Table 41: Addressable market size for graphene composites.
  • Table 42: Graphene properties relevant to application in polymer composites.
  • Table 43: Graphene product and application developers in the composites industry.
  • Table 44: Graphene in the aerospace market-applications, stage of commercialization and addressable market size.
  • Table 45: Graphene aerospace developments, 2013-2015.
  • Table 46: Graphene product and application developers in the aerospace industry.
  • Table 47: Graphene in the automotive market-applications, stage of commercialization and addressable market size.
  • Table 48: Graphene product and application developers in the automotive industry.
  • Table 49: Graphene in the biomedical and healthcare markets-applications, stage of commercialization and addressable market size.
  • Table 50: Graphene properties relevant to application in biomedicine and healthcare.
  • Table 51: Graphene medical and healthcare developments, 2013-2015.
  • Table 52: Graphene product and application developers in the medical and healthcare industry.
  • Figure 35: Global Paints and Coatings Market, share by end user market.
  • Table 53: Graphene in the coatings market-applications, stage of commercialization and addressable market size.
  • Table 54: Graphene properties relevant to application in coatings.
  • Figure 36: Water permeation through a brick without (left) and with (right) “graphene paint” coating.
  • Table 55: Graphene product and application developers in the coatings industry.
  • Figure 37: Degradation of organic dye molecules by graphene hybrid composite photocatalysts.
  • Table 56: Graphene filtration developments, 2013-2015.
  • Table 57: Graphene product and application developers in the filtration industry.
  • Table 58: Graphene in the energy market-Applications, stage of commercialization and addressable market size.
  • Table 59: Graphene Li-ion battery developments 2013-2015.
  • Figure 38: Skeleton Technologies ultracapacitor.
  • Figure 39: Zapgo supercapacitor phone charger.
  • Table 60: Comparative properties of graphene supercapacitors and lithium-ion batteries.
  • Table 61: Graphene supercapacitors developments 2013-2015.
  • Figure 40: Solar cell with nanowires and graphene electrode (Image credit: MIT).
  • Table 62: Graphene photovoltaics developments 2013-2015.
  • Table 63: Graphene fuel cell developments, 2013-2015.
  • Table 64: Graphene product and application developers in the energy industry.
  • Table 65: Graphene in the sensors market-applications, stage of commercialization and addressable market size.
  • Table 66: Graphene properties relevant to application in sensors.
  • Figure 41: GFET sensors.
  • Figure 42: Graphene Field Effect Transistor Schematic.
  • Figure 43: First generation point of care diagnostics.
  • Table 67: Comparison of ELISA (enzyme-linked immunosorbent assay) and graphene biosensor.
  • Table 68: Graphene sensors developments, 2013-2015.
  • Table 69: Graphene product and application developers in the sensors industry.
  • Table 70: Graphene properties relevant to application in 3D printing.
  • Table 71: Graphene product and application developers in the 3D printing industry.
  • Table 72: Graphene properties relevant to application in adhesives.
  • Table 73: Graphene product and application developers in the adhesives industry.
  • Table 74: Applications of graphene in lubricants.
  • Table 75: Graphene product and application developers in the lubricants industry.
  • Table 76: Graphene producers and types produced.
  • Table 77: Graphene industrial collaborations and target markets.
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