表紙
市場調査レポート

スマートサーフェスの世界市場 (2015〜2022年)

Smart Surfaces Markets 2015-2022

発行 n-tech Research, a NanoMarkets company 商品コード 326178
出版日 ページ情報 英文 108 Pages
納期: 即日から翌営業日
価格
本日の銀行送金レート: 1USD=102.12円で換算しております。
Back to Top
スマートサーフェスの世界市場 (2015〜2022年) Smart Surfaces Markets 2015-2022
出版日: 2015年03月17日 ページ情報: 英文 108 Pages
概要

当レポートでは、全世界のスマートサーフェス (スマート表面:多機能・高性能の表面素材) 市場について分析し、スマートサーフェスの特性や製造方法、主なエンドユーザー分野における活用方法、主な素材・技術、将来的な市場動向の見通し (今後8年間分)、今後の市場成長の方向性・可能性などについて調査・考察しております

エグゼクティブ・サマリー

第1章 イントロダクション

第2章 スマートサーフェスの技術と製造方法

  • スマートサーフェス:技術と種類
  • センサーおよびサーフェス
    • 低価格センサーの進化とそのコスト要因
    • サーフェス用センサーの種類
  • スマートサーフェス向けスマート素材
    • 自己修復素材
    • 自己浄材素材
    • 自己組織化素材
  • スマートサーフェスとスマート・コーティングの関係性
  • 製造方法のイノベーション
  • 本章の要点

第3章 建設業における現在・将来のスマートサーフェス市場

  • 建設業でのスマートサーフェスの市場機会
  • 自己調光ウィンドウ向けスマートコーティングによる市場開拓
  • 建築物における自己洗浄型サーフェスの市場機会
  • 建設業における自己修復型サーフェス
  • スマートソーラー用サーフェス
  • スマートフロア (床面)
  • よりスマートな壁面
  • 本章の要点

第4章 電力産業における現在・将来のスマートサーフェス市場

  • エネルギーの将来性と、スマートサーフェスに対する影響
  • 太陽光発電所向けスマートサーフェス
  • 風力タービン向けスマートサーフェス
  • 発電産業向けスマートサーフェス市場の将来予測 (今後8年間分)
  • 本章の要点

第5章 輸送機械向けの現在・将来のスマートサーフェス市場

  • 列車・船舶・航空機
  • 自動車産業向けの自己修復型サーフェス
  • 輸送市場でのガラス製スマートサーフェス
  • 自動車産業でのスマートサーフェスへの装置組み込み
  • 自動車・航空機向けの変色サーフェス
  • 自動車・船舶市場向けの防汚・防食・抗菌用スマートサーフェス
  • 着氷防止コーティング
  • 輸送機械向けスマートサーフェス市場でのその他の動向
  • 輸送機械向けスマートサーフェス市場の将来予測 (今後8年間分)
  • 本章の要点

第6章 医療産業向けスマートサーフェス

  • 医療分野でのスマートサーフェスの潜在的な用途
  • 生体適合性
  • 抗菌用スマートサーフェス
  • ドラッグデリバリー用サーフェス
  • 医薬品・医療向けスマートサーフェスの、その他の潜在的用途
  • 医療分野向けスマートサーフェス市場の将来予測 (今後8年間分)
  • 本章の要点

第7章 電子機器市場におけるスマートサーフェス

  • スマートサーフェス、ファッションエレクトロニクス、IoT (モノのインターネット)
  • ヒューマン・コンピュータ・インターフェースとしてのスマートサーフェス
  • 大面積エレクトロニクスと、電子機器用スマートサーフェスの製造
  • 電子機器産業向けスマートサーフェスの詳細動向 (今後8年間分)
  • 本章の要点

第8章 軍事・国内警備市場におけるスマートサーフェス:概略

  • 軍事・国内警備部門におけるスマートサーフェス
  • 迷彩用スマートサーフェス
  • レーダー吸収性材料
  • 耐食・防汚
  • 軍事・国内警備部門向けスマートサーフェスの将来予測 (今後8年間分)
  • 本章の要点

図表一覧

目次
Product Code: Nano-819

In this report, NanoMarkets identifies the emerging market opportunities for smart surfaces across a wide range of applications. Smart surfaces are capable of rearranging their morphology or composition in response to changes of the ambient environment. We expect smart surfaces to capitalize on the recent commercial successes of smart coatings and note both the extensive R&D in the field of smart surfaces and the beginnings of commercialization.

The report examines the use of metal oxides, polymers and biomaterials to create smart surfaces, as well as the use of novel patterning technologies including those derived from nanomanufacturing. We provide a roadmap and eight-year forecast (in volume and value terms) for smart surfaces in five important end-user sectors: energy, electronics, healthcare, automotive and aerospace, and the military. For each sector, we provide breakouts by materials type. In addition, the report also assesses the R&D and marketing strategies of the leading firms that are active in the commercialization of smart coatings.

NanoMarkets' market assessment of the smart coatings market is based both on the latest results from the lab and current marketing trends. For example, we examine how smart surfaces will play out in the Internet-of-Things and how recent changes in the energy sector will impact the prospects for smart surfaces. The report also examines how smart surfaces will find their place in smart environments where they must compete with embedded sensors and smart coatings.

The industry analysis in this report builds on NanoMarkets extensive program on the markets for smart coatings. NanoMarkets has been providing coverage in the smart coatings space for five years.

Table of Contents

Executive Summary

  • E.1. Smart Surfaces Creating Opportunities
    • E.1.1. Types of Smart Surfaces and their Commercialization
  • E.2. Opportunities for the Smart Surfaces in the Construction Sector
    • E.2.1. Smart Windows
    • E.2.2. Self-Cleaning Surfaces
    • E.2.3. Self-Healing Surfaces
    • E.2.4. Solar Panels and Smart Surfaces
  • E.3. Opportunities for Smart Surfaces in the Energy Sector
  • E.4. Opportunities for Smart Surfaces in the Transportation Sector
    • E.4.1. Self-Healing Smart Surfaces for Vehicles
    • E.4.2. Smart Glass in Transportation
    • E.4.3. Self-Coloring Interiors
    • E.4.4. Anti-Fouling Surfaces
  • E.5. Smart Surfaces in Medical and Healthcare Markets
  • E.6. Smart Surfaces for Electronics Markets
  • E.7. Barriers to Growth in the Smart Surface Market
  • E.8. Summary of Eight-Year Forecasts of Smart Surface Markets

Chapter One: Introduction

  • 1.1. Background to this Report
    • 1.1.1. Smart Cars: Where Smart Surfaces Begin
    • 1.1.2. Smart Surfaces: Essential to the Internet-of-Things?
    • 1.1.3. Smart Medical Surfaces
    • 1.1.4. Other
  • 1.2. Objective and Scope of Report
  • 1.3. Methodology of Report
    • 1.3.1. Forecasting Methodology
  • 1.4. Plan of Report

Chapter Two: Technologies and Manufacturing for Smart Surfaces

  • 2.1. Smart Surfaces: Technology and Types
    • 2.1.1. Smart Bandages as an Example
  • 2.2. Sensors and Surfaces
    • 2.2.1. Evolution of Low-Cost Sensors and the Cost Factor
    • 2.2.2. Types of Sensors for Surfaces
  • 2.3. Smart Materials for Smart Surfaces
    • 2.3.1. Self-Healing Materials
    • 2.3.2. Self-Cleaning Materials
    • 2.3.3. Self-Assembling Materials
  • 2.4. Relationship of Smart Surfaces to Smart Coatings
  • 2.5. Manufacturing Innovations
    • 2.5.1. Optical Lithography
    • 2.5.3. Functional Printing
    • 2.5.4. Nanomanufacturing Processes
    • 2.5.5. Layer-by-Layer Self-Assembly
  • 2.6. Key Points Made in this Chapter

Chapter Three: Current and Future Markets for Smart Surfaces in the Construction Industry

  • 3.1. Smart Surface Opportunities in Construction
  • 3.2. Smart Coatings for Self-Dimming Windows Paving the Way
    • 3.2.1. Key Trends Shaping Opportunities in the Self-Tinting Glass Market
    • 3.2.2. Passive Self-Tinting Windows: Thermochromic and Photochromic Coatings
    • 3.2.3. Active Self-Dimming Windows: Electrochromic, SPD and PDLC
    • 3.2.4. How Much Smartness Does a Self-Dimming Window Require: The Need for Smart Surfaces
  • 3.3. Opportunities for Self-Cleaning Surfaces in Buildings
    • 3.3.1. Hydrophobic Surfaces versus Hydrophilic Surfaces
    • 3.3.2. Improvements to Self-Cleaning Surfaces Using More Complex Material Systems
    • 3.3.3. Adding Functionality to Self-Cleaning Surfaces
  • 3.4. Self-Healing Surfaces in Construction
    • 3.4.1. Emerging Self-Healing Technologies
    • 3.4.2. The Future of Self-Healing Surfaces in Construction
  • 3.5. Smart Solar Surfaces
    • 3.5.1. Monolithically Integrated BIPV Considered as a Smart Surface
    • 3.5.2. Self-Cleaning Solar Surfaces
    • 3.5.3. Solar for Powering Smart Windows
  • 3.6. Smart Floors
    • 3.6.1. Air Purification in Smart Floors
    • 3.6.2. Smart Floors That Track
  • 3.4. Smarter Walls
  • 3.6. Eight-Year Forecasts of Smart Surfaces in the Construction Sector
    • 3.6.1. Impact of the Worldwide Construction Market
  • 3.6. Key Points from this Chapter

Chapter Four: Current and Future Markets for Smart Surfaces in Energy Generation

  • 4.1. The Future of Energy and its Impact on Smart Surfaces
  • 4.2. Smart Surfaces in Solar Farms
  • 4.3. Smart Surfaces for Wind Turbines
    • 4.3.1. Existing Products
    • 4.3.2. Future Products
  • 4.4. Eight-Year Forecasts of Smart Surfaces in the Energy Generation Sector
  • 4.5. Key Points from this Chapter

Chapter Five: Current and Future Markets for Smart Surfaces in Transportation Vehicles

  • 5.1. Trains and Boats and Planes
    • 5.1.1. Functional Advantages of Smart Surfaces in Transportation
    • 5.1.2. Aesthetic Advantages of Smart Surfaces in Smart Surfaces
  • 5.2. Self-Healing Surfaces in the Automotive Industry
    • 5.2.1. Organizations to Watch in Automotive Self-Healing Surface Markets
    • 5.2.2. Future Developments in Self-Healing Surfaces for the Automotive Market
    • 5.2.3. Self-Healing Surfaces for Other Transportation Markets
  • 5.3. Smart Glass Surfaces in the Transportation Market
    • 5.3.1. Four Key Factors Promoting the Use of Smart Glass in the Automotive Sector
    • 5.3.2. Self-Tinting Glass in the Automotive Sector
    • 5.3.3. PDLC Privacy Glass in the Automotive Sector
    • 5.3.4. Smart Mirrors
    • 5.3.5. Self-Cleaning Glass
    • 5.3.6. Self-Healing Glass in Automotive Markets
    • 5.3.7. Embedded Intelligence in Smart Auto Glass Surfaces
    • 5.3.8. Six Companies Shaping the Smart Auto Glass Business
  • 5.4. Embedding Devices in Smart Surfaces in the Automotive Industry
  • 5.5. Color-Changing Surfaces for Cars and Planes
  • 5.6. Smart Antifouling, Anticorrosion and Antimicrobial Surfaces for Cars and Marine Markets
    • 5.6.1. Current Chemistries for Antifouling Surfaces
    • 5.6.2. Elimination of Copper in Anti-Fouling Surfaces
    • 5.6.3. Antifouling Surfaces with On-demand Features for Commercial Ships
    • 5.6.4. Smart Sensors for Marine Applications yet to gain Significant Traction
    • 5.6.5. Other Developments in Smart Anticorrosive Surfaces
  • 5.7. De-icing Coatings
  • 5.8. Other Developments in Smart Surfaces for Transportation
    • 5.8.1. Smart Tires
    • 5.8.2. Self-Stratifying Coatings
    • 5.8.3. Self-Assembled Monolayers
  • 5.9. Eight-Year Forecast of Smart Surfaces in Transportation
  • 5.10. Key Points from this Chapter

Chapter Six: Smart Surfaces in the Healthcare Industry

  • 6.1. Possible Uses for Smart Surfaces in Healthcare
  • 6.2. Biocompatability
  • 6.3. Antimicrobial Smart Surfaces
    • 6.3.1. Smart Antimicrobial Surfaces Getting Smarter
    • 6.3.2. The Use of Silver in Smart Antimicrobials
  • 6.4. Drug Delivery Surfaces
    • 6.4.1. Examples of R&D in Smart Drug Delivery Surfaces
  • 6.5. Other Potential Applications for Smart Surfaces in Medicine and Healthcare
    • 6.5.1. Cell Culture
    • 6.5.2. Surfaces, Biosensors and Diagnostics
    • 6.5.3. Bioseparation and Miniaturized Microfluidics
  • 6.6. Eight-Year Forecasts of Smart Surfaces in the Medical Sector
  • 6.7. Key Points from this Chapter

Chapter Seven: Smart Surfaces in the Electronics Market

  • 7.1. Smart Surfaces, Fashion Electronics and the Internet-of-Things
    • 7.1.1. The IoT and Smart Surfaces
    • 7.1.2. Smart Surfaces for Fashion Electronics
  • 7.2. Smart Surfaces as Human Computer Interfaces
  • 7.3. Large-Area Electronics and the Manufacture of Smart Electronics Surfaces
    • 7.3.1. Manufacturing Smart Electronic Surfaces
    • 7.3.2. Flexible and Curved Surfaces and Smart Electronics
  • 7.4. Eight-Year Forecasts of Smart Surfaces in the Electronics Sector
  • 7.5. Key Points from this Chapter

Chapter Eight: A Coda on Smart Surfaces in Military and Domestic Security Markets

  • 8.1. Smart Surfaces in Military and Domestic Security
  • 8.2. Smart Surfaces for Camouflage
  • 8.3. Radar Absorbent Materials
  • 8.4. Anticorrosion and Anti-Fouling
  • 8.5. Eight-Year Forecasts of Smart Surfaces in the Medical Sector
  • 8.6. Key Points from this Chapter
  • Acronyms and Abbreviations Used In this Report
  • About the Author

List of Exhibits

  • Exhibit E-1: Summary of Worldwide Smart Surfaces Market by Revenues ($ Millions)
  • Exhibit 2-1: Advantages of Printing for Fabricating Low-Cost Sensors for Smart Surfaces
  • Exhibit 3-1: Customer Choice Possibilities of Smart Coatings for Smart Windows
  • Exhibit 3-2: Major Research Initiatives and Trends in Self-Healing Surface Technology
  • Exhibit 3-3: Smart Wall Functionality and Markets
  • Exhibit 3-4: Worldwide Market for Smart Surfaces in the Construction Industry.
  • Exhibit 4-1: Worldwide Market for Smart Surfaces in the Energy Sector
  • Exhibit 5-1: Factors Shaping Demand for Smart Glass in the Automotive Sector
  • Exhibit 5-2: Firms to Watch in the Smart Windows Market
  • Exhibit 5-3: Worldwide Market for Smart Surfaces in the Transportation Sector
  • Exhibit 6-1: Worldwide Market for Smart Surfaces in the Medical Sector
  • Exhibit 7-1: Worldwide Market for Smart Surfaces in the Electronics Sector
  • Exhibit 8-1: Worldwide Market for Smart Surfaces in the Military and Domestic Security Sector
Back to Top