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市場調查報告書

溶膠-凝膠塗料的全球市場:2020∼2030年

The Global Market for Sol-Gel Coatings 2020-2030

出版商 Future Markets, Inc. 商品編碼 984871
出版日期 內容資訊 英文 580 Pages, 161 Figures, 158 Tables
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溶膠-凝膠塗料的全球市場:2020∼2030年 The Global Market for Sol-Gel Coatings 2020-2030
出版日期: 2021年01月18日內容資訊: 英文 580 Pages, 161 Figures, 158 Tables
簡介

透過溶膠-凝膠流程調製的有機/無機混合塗料,在玻璃,金屬和聚合物基材上的應用已經獲得了相當多的研究和商業興趣。

溶膠-凝膠塗料的多功能性已為電子,光學,太陽能收集,航空航天,汽車工程,海洋保護,紡織品和醫療保健等行業提供了解決方案。 溶膠-凝膠法還允許控制多功能雜化材料的合成,其中將有機,無機以及某些情況下的生物前體和聚合物以奈米級進行混合。

本報告提供全球溶膠-凝膠塗料市場相關調查,全球市場整體性定量資料與預測,目前市場相關定性分析及終端用戶市場上未來趨勢相關預測,終端用戶市場分析與技術時間軸,及主要企業簡介等資訊。

目錄

第1章 摘要整理

  • 溶膠-凝膠塗料
  • 相對於傳統塗料的奈米塗料的優點
    • 溶膠-凝膠塗料的優點
  • 溶膠-凝膠塗料的製造和應用
  • 塗料市場改善和混亂
  • 奈米塗料的終端用戶市場
  • 奈米塗料市場
  • 全球市場規模,成果及估計
    • 全球奈米塗料收益
    • 地區的奈米塗料需求
  • 市場課題

第2章 奈米塗料

  • 特性
  • 使用奈米塗料的優點
    • 奈米塗料的種類
  • 製造及合成方法

第3章 溶膠凝膠法

  • 溶膠-凝膠塗料的特性和優點
  • 溶膠凝膠法的優點
  • 溶膠-凝膠流程的問題

第4章 疏水性塗料和表面

  • 親水性塗料
  • 疏水性塗料
    • 特性
    • 面膜的應用程式

第5章 超疏水性塗料和表面

  • 特性
    • 抗菌使用
  • 耐用性的問題

第6章 疏油性及疏油性塗料和表面

第7章 溶膠-凝膠塗料所使用的奈米材料

  • 石墨烯
    • 特性及塗料應用
  • 奈米碳管(MWCNT及SWCNT)
    • 特性和應用
    • SWCNT
  • 富勒烯
    • 特性
    • 抗菌作用
  • 二氧化矽/二氧化矽奈米粒子(Nano-SiO2)
    • 特性和應用
  • 奈米銀
  • 二氧化鈦奈米粒子(奈米TiO2)
  • 氧化鋁奈米粒子(Al2O3-NPs)
  • 氧化鋅奈米粒子(ZnO-NP)
  • 樹狀聚合物
  • 奈米鑽石
  • 奈米纖維素(纖維素奈米纖維,纖維素奈米水晶,細菌纖維素)
  • 幾丁聚醣奈米粒子
    • 特性
    • 傷口敷料
    • 塗料和薄膜包裝
    • 食品貯存庫
  • 銅奈米粒子
    • 特性
    • 抗菌奈米塗料的應用

第8章 溶膠-凝膠塗料的應用

  • 指紋防止奈米塗料
    • 市場概要
    • 市場評估
    • 市場促進因素與趨勢
    • 應用
    • 全球市場規模
    • 產品開發商
  • 抗菌、抗病毒奈米塗料
  • 防腐蝕奈米塗料
  • 耐摩耗性、耐摩耗性的奈米塗料
  • 阻隔奈米塗料
  • 防骯髒、簡易清洗奈米塗料
  • 自我清潔奈米塗料
  • 光觸媒奈米塗料
  • 耐紫外線奈米塗料
  • 熱阻隔、阻燃性奈米塗料
  • 防冰、除冰奈米塗料
  • 反射防止奈米塗料

第9章 市場區隔分析:各最終消費者市場

  • 航空、航太
    • 市場促進因素與趨勢
    • 應用
    • 全球市場規模
    • 企業
  • 汽車
  • 建設
  • 電子產品
  • 家用照護,衛生及室內空氣品質
  • 船舶
  • 醫療、醫療保健
  • 軍事、防衛
  • 包裝
  • 紡織品、服裝
  • 能源
  • 石油、天然氣
  • 工具、加工

第10章 企業簡介

第11章 調查手法

  • 研究的目的
  • 市場定義
    • 奈米材料的性質
    • 分類

第12章 參考文件

目錄

Organic/inorganic hybrid coatings prepared via the sol-gel process have garnered considerable research and commercial interest for application on glass, metallic and polymeric substrates .

The sol-gel process is considered attractive due to simple processing and relative low-cost, resulting in the creation of multi-functional, protective surfaces. This is due to the unique structure and properties of silica-based coatings and of hybrid inorganic-organic silicas in particular.

Enhanced coatings and surfaces obtained via this low-temperature route display a large range of bulk and surface properties that can be tailored by specific applications. The versatility of sol-gel coatings has enabled solutions in industries such as electronics, optics, solar energy harvesting, aerospace, automotive engineering, marine protection, textiles and healthcare. The sol-gel method also allows for control of the synthesis of multifunctional hybrid materials, where the organic, inorganic and, in some cases, biological precursors and polymers are mixed at a nanometer scale.

Properties that can be achieved with sol-gel coatings include:

  • Hydrophobic surfaces;
  • Anti-fingerprinting;
  • Oleophobic surfaces;
  • Anti-microbial surfaces;
  • Easy to clean surfaces;
  • Protective transparent coatings;
  • Corrosion resistance;
  • Low friction;
  • Chemical resistance;
  • Free of fluoropolymers;
  • Antistatic surfaces;
  • Conducting/semi-conducting surfaces;
  • Extreme mechanical wear resistant properties;
  • UV protection.

End user markets include:

  • construction (pipes, facades, bridges)
  • automotive (paint surface treatments, metal parts, metal structures,window, mirrors and lamps, plastic hoods)
  • marine
  • electronics (components, screens and displays, plastic and metal parts)
  • sanitary
  • oil and gas (pipes)
  • energy (wind power structures and bladesglass surfaces on solar panels)
  • paper coatings.
  • food manufacturing.
  • cookware.

Report contents include:

  • Comprehensive quantitative data and forecasts for the global sol-gel coatings market.
  • Qualitative insight and perspective on the current market and future trends in end user markets.
  • End user market analysis and technology timelines.
  • Tables illustrating market size and by end user demand.
  • Full company profiles of sol-gel coatings application developers including technology descriptions, products, contact details, and end user markets.

TABLE OF CONTENTS

1. EXECUTIVE SUMMARY

  • 1.1. Sol-gel coatings
  • 1.2. Advantages of nanocoatings over traditional coatings
    • 1.2.1. Advantages of sol-gel coatings
  • 1.3. Sol-gel coatings fabrication and application
  • 1.4. Improvements and disruption in coatings markets
  • 1.5. End user market for nanocoatings
  • 1.6. The nanocoatings market in 2020
  • 1.7. Global market size, historical and estimated to 2020
    • 1.7.1. Global revenues for nanocoatings 2010-2030
    • 1.7.2. Regional demand for nanocoatings
  • 1.8. Market challenges

2. NANOCOATINGS

  • 2.1. Properties
  • 2.2. Benefits of using nanocoatings
    • 2.2.1. Types of nanocoatings
  • 2.3. Production and synthesis methods

3. THE SOL-GEL PROCESS

  • 3.1. Properties and benefits of sol-gel coatings
  • 3.2. Advantages of the sol-gel process
  • 3.3. Issues with the sol-gel process

4. HYDROPHOBIC COATINGS AND SURFACES

  • 4.1. Hydrophilic coatings
  • 4.2. Hydrophobic coatings
    • 4.2.1. Properties
    • 4.2.2. Application in facemasks

5. SUPERHYDROPHOBIC COATINGS AND SURFACES

  • 5.1. Properties
    • 5.1.1. Antibacterial use
  • 5.2. Durability issues

6. OLEOPHOBIC AND OMNIPHOBIC COATINGS AND SURFACES

7. NANOMATERIALS USED IN SOL-GEL COATINGS

  • 7.1. Graphene
    • 7.1.1. Properties and coatings applications
      • 7.1.1.1. Anti-corrosion coatings
      • 7.1.1.2. Graphene oxide
      • 7.1.1.3. Reduced graphene oxide (rGO)
      • 7.1.1.4. Anti-icing
      • 7.1.1.5. Barrier coatings
      • 7.1.1.6. Heat protection
      • 7.1.1.7. Smart windows
  • 7.2. Carbon nanotubes (MWCNT and SWCNT)
    • 7.2.1. Properties and applications
      • 7.2.1.1. Conductive films and coatings
      • 7.2.1.2. EMI shielding
      • 7.2.1.3. Anti-fouling
      • 7.2.1.4. Flame retardant
      • 7.2.1.5. Antimicrobial activity
    • 7.2.2. SWCNTs
      • 7.2.2.1. Properties and applications
  • 7.3. Fullerenes
    • 7.3.1. Properties
    • 7.3.2. Antimicrobial activity
  • 7.4. Silicon dioxide/silica nanoparticles (Nano-SiO2)
    • 7.4.1. Properties and applications
      • 7.4.1.1. Antimicrobial and antiviral activity
      • 7.4.1.2. Easy-clean and dirt repellent
      • 7.4.1.3. Anti-fogging
      • 7.4.1.4. Scratch and wear resistance
      • 7.4.1.5. Anti-reflection
  • 7.5. Nanosilver
    • 7.5.1. Properties and applications
      • 7.5.1.1. Anti-bacterial
      • 7.5.1.2. Silver nanocoatings
      • 7.5.1.3. Antimicrobial silver paints
      • 7.5.1.4. Anti-reflection
      • 7.5.1.5. Textiles
      • 7.5.1.6. Wound dressings
      • 7.5.1.7. Consumer products
      • 7.5.1.8. Air filtration
  • 7.6. Titanium dioxide nanoparticles (nano-TiO2)
    • 7.6.1. Properties and applications
      • 7.6.1.1. Exterior and construction glass coatings
      • 7.6.1.2. Outdoor air pollution
      • 7.6.1.3. Interior coatings
      • 7.6.1.4. Improving indoor air quality
      • 7.6.1.5. Medical facilities
      • 7.6.1.6. Waste Water Treatment
      • 7.6.1.7. UV protection coatings
      • 7.6.1.8. Antimicrobial coating indoor light activation
  • 7.7. Aluminium oxide nanoparticles (Al2O3-NPs)
    • 7.7.1. Properties and applications
  • 7.8. Zinc oxide nanoparticles (ZnO-NPs)
    • 7.8.1. Properties and applications
      • 7.8.1.1. UV protection
      • 7.8.1.2. Anti-bacterial
  • 7.9. Dendrimers
    • 7.9.1. Properties and applications
  • 7.10. Nanodiamonds
    • 7.10.1. Properties and applications
  • 7.11. Nanocellulose (Cellulose nanofibers, cellulose nanocrystals and bacterial cellulose)
    • 7.11.1. Properties and applications
      • 7.11.1.1. Cellulose nanofibers (CNF)
      • 7.11.1.2. NanoCrystalline Cellulose (NCC)
      • 7.11.1.3. Bacterial Cellulose (BCC)
      • 7.11.1.4. Abrasion and scratch resistance
      • 7.11.1.5. UV-resistant
      • 7.11.1.6. Superhydrophobic coatings
      • 7.11.1.7. Gas barriers
      • 7.11.1.8. Anti-bacterial
  • 7.12. Chitosan nanoparticles
    • 7.12.1. Properties
    • 7.12.2. Wound dressings
    • 7.12.3. Packaging coatings and films
    • 7.12.4. Food storage
  • 7.13. Copper nanoparticles
    • 7.13.1. Properties
    • 7.13.2. Application in antimicrobial nanocoatings

8. APPLICATIONS OF SOL-GEL COATINGS

  • 8.1. ANTI-FINGERPRINT NANOCOATINGS
    • 8.1.1. Market overview
    • 8.1.2. Market assessment
    • 8.1.3. Market drivers and trends
    • 8.1.4. Applications
      • 8.1.4.1. Touchscreens
      • 8.1.4.2. Spray-on anti-fingerprint coating
    • 8.1.5. Global market size
    • 8.1.6. Product developers
  • 8.2. ANTI-MICROBIAL AND ANTI-VIRAL NANOCOATINGS
    • 8.2.1. Mode of action
    • 8.2.2. Anti-viral coatings and surfaces
    • 8.2.3. Market overview
    • 8.2.4. Market assessment
    • 8.2.5. Market drivers and trends
    • 8.2.6. Applications
    • 8.2.7. Global market size
    • 8.2.8. Product developers
  • 8.3. ANTI-CORROSION NANOCOATINGS
    • 8.3.1. Market overview
    • 8.3.2. Market assessment
    • 8.3.3. Market drivers and trends
    • 8.3.4. Applications
      • 8.3.4.1. Smart self-healing coatings
      • 8.3.4.2. Superhydrophobic coatings
      • 8.3.4.3. Graphene
    • 8.3.5. Global market size
    • 8.3.6. Product developers
  • 8.4. ABRASION & WEAR-RESISTANT NANOCOATINGS
    • 8.4.1. Market overview
    • 8.4.2. Market assessment
    • 8.4.3. Market drivers and trends
    • 8.4.4. Applications
    • 8.4.5. Global market size
    • 8.4.6. Product developers
  • 8.5. BARRIER NANOCOATINGS
    • 8.5.1. Market assessment
    • 8.5.2. Market drivers and trends
    • 8.5.3. Applications
      • 8.5.3.1. Food and Beverage Packaging
      • 8.5.3.2. Moisture protection
      • 8.5.3.3. Graphene
    • 8.5.4. Global market size
    • 8.5.5. Product developers
  • 8.6. ANTI-FOULING AND EASY-TO-CLEAN NANOCOATINGS
    • 8.6.1. Market overview
    • 8.6.2. Market assessment
    • 8.6.3. Market drivers and trends
    • 8.6.4. Applications
      • 8.6.4.1. Hydrophobic and olephobic coatings
      • 8.6.4.2. Anti-graffiti
    • 8.6.5. Global market size
    • 8.6.6. Product developers
  • 8.7. SELF-CLEANING NANOCOATINGS
    • 8.7.1. Market overview
    • 8.7.2. Market assessment
    • 8.7.3. Market drivers and trends
    • 8.7.4. Applications
    • 8.7.5. Global market size
    • 8.7.6. Product developers
  • 8.8. PHOTOCATALYTIC NANOCOATINGS
    • 8.8.1. Market overview
    • 8.8.2. Market assessment
    • 8.8.3. Market drivers and trends
    • 8.8.4. Applications
      • 8.8.4.1. Self-Cleaning coatings-glass
      • 8.8.4.2. Self-cleaning coatings-building and construction surfaces
      • 8.8.4.3. Photocatalytic oxidation (PCO) indoor air filters
      • 8.8.4.4. Water treatment
      • 8.8.4.5. Medical facilities
      • 8.8.4.6. Antimicrobial coating indoor light activation
    • 8.8.5. Global market size
    • 8.8.6. Product developers
  • 8.9. UV-RESISTANT NANOCOATINGS
    • 8.9.1. Market overview
    • 8.9.2. Market assessment
    • 8.9.3. Market drivers and trends
    • 8.9.4. Applications
      • 8.9.4.1. Textiles
      • 8.9.4.2. Wood coatings
    • 8.9.5. Global market size
    • 8.9.6. Product developers
  • 8.10. THERMAL BARRIER AND FLAME RETARDANT NANOCOATINGS
    • 8.10.1. Market overview
    • 8.10.2. Market assessment
    • 8.10.3. Market drivers and trends
    • 8.10.4. Applications
    • 8.10.5. Global market size
    • 8.10.6. Product developers
  • 8.11. ANTI-ICING AND DE-ICING NANOCOATINGS
    • 8.11.1. Market overview
    • 8.11.2. Market assessment
    • 8.11.3. Market drivers and trends
    • 8.11.4. Applications
      • 8.11.4.1. Hydrophobic and superhydrophobic coatings (HSH)
      • 8.11.4.2. Heatable coatings
      • 8.11.4.3. Anti-freeze protein coatings
    • 8.11.5. Global market size
    • 8.11.6. Product developers
  • 8.12. ANTI-REFLECTIVE NANOCOATINGS
    • 8.12.1. Market overview
    • 8.12.2. Market drivers and trends
    • 8.12.3. Applications
    • 8.12.4. Global market size
    • 8.12.5. Product developers

9. MARKET SEGMENT ANALYSIS, BY END USER MARKET

  • 9.1. AVIATION AND AEROSPACE
    • 9.1.1. Market drivers and trends
    • 9.1.2. Applications
      • 9.1.2.1. Thermal protection
      • 9.1.2.2. Icing prevention
      • 9.1.2.3. Conductive and anti-static
      • 9.1.2.4. Corrosion resistant
      • 9.1.2.5. Insect contamination
    • 9.1.3. Global market size
      • 9.1.3.1. Nanocoatings opportunity
      • 9.1.3.2. Global revenues 2010-2030
    • 9.1.4. Companies
  • 9.2. AUTOMOTIVE
    • 9.2.1. Market drivers and trends
    • 9.2.2. Applications
      • 9.2.2.1. Anti-scratch nanocoatings
      • 9.2.2.2. Conductive coatings
      • 9.2.2.3. Hydrophobic and oleophobic
      • 9.2.2.4. Anti-corrosion
      • 9.2.2.5. UV-resistance
      • 9.2.2.6. Thermal barrier
      • 9.2.2.7. Flame retardant
      • 9.2.2.8. Anti-fingerprint
      • 9.2.2.9. Anti-bacterial
      • 9.2.2.10. Self-healing
    • 9.2.3. Global market size
      • 9.2.3.1. Nanocoatings opportunity
      • 9.2.3.2. Global revenues 2010-2030
    • 9.2.4. Companies
  • 9.3. CONSTRUCTION
    • 9.3.1. Market drivers and trends
    • 9.3.2. Applications
      • 9.3.2.1. Protective coatings for glass, concrete and other construction materials
      • 9.3.2.2. Photocatalytic nano-TiO2 coatings
      • 9.3.2.3. Anti-graffiti
      • 9.3.2.4. UV-protection
      • 9.3.2.5. Titanium dioxide nanoparticles
      • 9.3.2.6. Zinc oxide nanoparticles
    • 9.3.3. Global market size
      • 9.3.3.1. Nanocoatings opportunity
      • 9.3.3.2. Global revenues 2010-2030
    • 9.3.4. Companies
  • 9.4. ELECTRONICS
    • 9.4.1. Market drivers
    • 9.4.2. Applications
      • 9.4.2.1. Transparent functional coatings
      • 9.4.2.2. Anti-reflective coatings for displays
      • 9.4.2.3. Waterproof coatings
      • 9.4.2.4. Conductive nanocoatings and films
      • 9.4.2.5. Anti-fingerprint
      • 9.4.2.6. Anti-abrasion
      • 9.4.2.7. Conductive
      • 9.4.2.8. Self-healing consumer electronic device coatings
      • 9.4.2.9. Flexible and stretchable electronics
    • 9.4.3. Global market size
      • 9.4.3.1. Nanocoatings opportunity
      • 9.4.3.2. Global revenues 2010-2030
    • 9.4.4. Companies
  • 9.5. HOUSEHOLD CARE, SANITARY AND INDOOR AIR QUALITY
    • 9.5.1. Market drivers and trends
    • 9.5.2. Applications
      • 9.5.2.1. Self-cleaning and easy-to-clean
      • 9.5.2.2. Food preparation and processing
      • 9.5.2.3. Indoor pollutants and air quality
    • 9.5.3. Global market size
      • 9.5.3.1. Nanocoatings opportunity
      • 9.5.3.2. Global revenues 2010-2030
    • 9.5.4. Companies
  • 9.6. MARINE
    • 9.6.1. Market drivers and trends
    • 9.6.2. Applications
    • 9.6.3. Global market size
      • 9.6.3.1. Nanocoatings opportunity
      • 9.6.3.2. Global revenues 2010-2030
    • 9.6.4. Companies
  • 9.7. MEDICAL & HEALTHCARE
    • 9.7.1. Market drivers and trends
    • 9.7.2. Applications
      • 9.7.2.1. Anti-fouling coatings
      • 9.7.2.2. Anti-microbial, anti-viral and infection control
      • 9.7.2.3. Medical textiles
      • 9.7.2.4. Nanosilver
      • 9.7.2.5. Medical device coatings
    • 9.7.3. Global market size
      • 9.7.3.1. Nanocoatings opportunity
      • 9.7.3.2. Global revenues 2010-2030
    • 9.7.4. Companies
  • 9.8. MILITARY AND DEFENCE
    • 9.8.1. Market drivers and trends
    • 9.8.2. Applications
      • 9.8.2.1. Textiles
      • 9.8.2.2. Military equipment
      • 9.8.2.3. Chemical and biological protection
      • 9.8.2.4. Decontamination
      • 9.8.2.5. Thermal barrier
      • 9.8.2.6. EMI/ESD Shielding
      • 9.8.2.7. Anti-reflection
    • 9.8.3. Global market size
      • 9.8.3.1. Nanocoatings opportunity
      • 9.8.3.2. Global market revenues 2010-2030
    • 9.8.4. Companies
  • 9.9. PACKAGING
    • 9.9.1. Market drivers and trends
    • 9.9.2. Applications
      • 9.9.2.1. Barrier films
      • 9.9.2.2. Anti-microbial
      • 9.9.2.3. Biobased and active packaging
    • 9.9.3. Global market size
      • 9.9.3.1. Nanocoatings opportunity
      • 9.9.3.2. Global market revenues 2010-2030
    • 9.9.4. Companies
  • 9.10. TEXTILES AND APPAREL
    • 9.10.1. Market drivers and trends
    • 9.10.2. Applications
      • 9.10.2.1. Protective textiles
      • 9.10.2.2. UV-resistant textile coatings
      • 9.10.2.3. Conductive coatings
    • 9.10.3. Global market size
      • 9.10.3.1. Nanocoatings opportunity
      • 9.10.3.2. Global market revenues 2010-2030
    • 9.10.4. Companies
  • 9.11. ENERGY
    • 9.11.1. Market drivers and trends
    • 9.11.2. Applications
      • 9.11.2.1. Wind energy
      • 9.11.2.2. Solar
      • 9.11.2.3. Anti-reflection
      • 9.11.2.4. Gas turbine coatings
    • 9.11.3. Global market size
      • 9.11.3.1. Nanocoatings opportunity
      • 9.11.3.2. Global market revenues 2010-2030
    • 9.11.4. Companies
  • 9.12. OIL AND GAS
    • 9.12.1. Market drivers and trends
    • 9.12.2. Applications
      • 9.12.2.1. Anti-corrosion pipelines
      • 9.12.2.2. Drilling in sub-zero climates
    • 9.12.3. Global market size
      • 9.12.3.1. Nanocoatings opportunity
      • 9.12.3.2. Global market revenues 2010-2030
    • 9.12.4. Companies
  • 9.13. TOOLS AND MACHINING
    • 9.13.1. Market drivers and trends
    • 9.13.2. Applications
    • 9.13.3. Global market size
      • 9.13.3.1. Global market revenues 2010-2030
    • 9.13.4. Companies

10. COMPANY PROFILES

11. RESEARCH METHODOLOGY

  • 11.1. Aims and objectives of the study
  • 11.2. Market definition
    • 11.2.1. Properties of nanomaterials
    • 11.2.2. Categorization

12. REFERENCES

TABLES

  • Table 1: Properties of nanocoatings.
  • Table 2: Market drivers and trends in nanocoatings.
  • Table 3: End user markets for nanocoatings.
  • Table 4: Global revenues for nanocoatings, 2010-2030, millions USD.
  • Table 5: Market and technical challenges for nanocoatings.
  • Table 6: Technology for synthesizing nanocoatings agents.
  • Table 7: Film coatings techniques.
  • Table 8. Contact angles of hydrophilic, super hydrophilic, hydrophobic and superhydrophobic surfaces.
  • Table 9: Disadvantages of commonly utilized superhydrophobic coating methods.
  • Table 10: Applications of oleophobic & omniphobic coatings.
  • Table 11: Nanomaterials used in sol-gel coatings and applications.
  • Table 12: Graphene properties relevant to application in coatings.
  • Table 13: Uncoated vs. graphene coated (right) steel wire in corrosive environment solution after 30 days.
  • Table 14. Bactericidal characters of graphene-based materials.
  • Table 15: Market and applications for SWCNTs in coatings.
  • Table 16. Types of carbon-based nanoparticles as antimicrobial agent, their mechanisms of action and characteristics.
  • Table 17. Applications of nanosilver in coatings.
  • Table 18. Markets and applications for antimicrobial nanosilver nanocoatings.
  • Table 19. Antibacterial effects of ZnO NPs in different bacterial species.
  • Table 20. Market and applications for NDs in anti-friction and anti-corrosion coatings.
  • Table 21. Applications of nanocellulose in coatings.
  • Table 22: Applications of cellulose nanofibers(CNF).
  • Table 23: Applications of bacterial cellulose (BC).
  • Table 24. Mechanism of chitosan antimicrobial action.
  • Table 25. Market overview for anti-fingerprint nanocoatings.
  • Table 26: Market assessment for anti-fingerprint nanocoatings.
  • Table 27. Market drivers and trends for anti-fingerprint nanocoatings.
  • Table 28: Anti-fingerprint coatings product and application developers.
  • Table 29. Growth Modes of Bacteria and characteristics.
  • Table 30. Anti-microbial nanocoatings-Nanomaterials used, principles, properties and applications
  • Table 31. Market assessment for anti-microbial nanocoatings.
  • Table 32. Market drivers and trends for anti-microbial and anti-viral nanocoatings.
  • Table 33. Nanomaterials used in anti-microbial and anti-viral nanocoatings and applications.
  • Table 34: Anti-microbial amd anti-viral nanocoatings product and application developers.
  • Table 35. Market overview for anti-corrosion nanocoatings.
  • Table 36: Market assessment for anti-corrosion nanocoatings.
  • Table 37. Market drivers and trends for use of anti-corrosion nanocoatings.
  • Table 38: Superior corrosion protection using graphene-added epoxy coatings, right, as compared to a commercial zinc-rich epoxy primer, left.
  • Table 39: Applications for anti-corrosion nanocoatings.
  • Table 40: Opportunity for anti-corrosion nanocoatings by 2030.
  • Table 41: Anti-corrosion nanocoatings product and application developers.
  • Table 42. Market overview for abrasion and wear-resistant nanocoatings.
  • Table 43. Market assessment for abrasion and wear-resistant nanocoatings
  • Table 44. Market driversaand trends for use of abrasion and wear resistant nanocoatings.
  • Table 45. Applications for abrasion and wear-resistant nanocoatings.
  • Table 46. Potential addressable market for abrasion and wear-resistant nanocoatings
  • Table 47: Abrasion and wear resistant nanocoatings product and application developers.
  • Table 48.: Market assessment for barrier nanocoatings and films.
  • Table 49: Market drivers and trends for barrier nanocoatings
  • Table 50. Potential addressable market for barrier nanocoatings.
  • Table 51: Barrier nanocoatings product and application developers.
  • Table 52: Anti-fouling and easy-to-clean nanocoatings-Nanomaterials used, principles, properties and applications.
  • Table 53. Market assessment for anti-fouling and easy-to-clean nanocoatings.
  • Table 54. Market drivers and trends for use of anti-fouling and easy to clean nanocoatings.
  • Table 55. Anti-fouling and easy-to-clean nanocoatings markets, applications and potential addressable market.
  • Table 56: Anti-fouling and easy-to-clean nanocoatings product and application developers.
  • Table 57. Market overview for self-cleaning nanocoatings.
  • Table 58. Market assessment for self-cleaning (bionic) nanocoatings.
  • Table 59. Market drivers and trends for self-cleaning nanocoatings.
  • Table 60. Self-cleaning (bionic) nanocoatings-Markets and applications.
  • Table 61: Self-cleaning (bionic) nanocoatings product and application developers.
  • Table 62. Market overview for photocatalytic nanocoatings.
  • Table 63. Market assessment for photocatalytic nanocoatings.
  • Table 64. Market drivers and trends in photocatalytic nanocoatings.
  • Table 65. Photocatalytic nanocoatings-Markets, applications and potential addressable market size by 2027.
  • Table 66: Self-cleaning (photocatalytic) nanocoatings product and application developers.
  • Table 67. Market overview for UV resistant nanocoatings.
  • Table 68. Market assessment for UV-resistant nanocoatings.
  • Table 69: Market assessment for UV-resistant nanocoatings.
  • Table 70. Market drivers and trends in UV-resistant nanocoatings.
  • Table 71. UV-resistant nanocoatings-Markets, applications and potential addressable market.
  • Table 72: UV-resistant nanocoatings product and application developers.
  • Table 73. Market overview for thermal barrier and flame retardant nanocoatings.
  • Table 74. Market assessment for thermal barrier and flame retardant nanocoatings.
  • Table 75. Market drivers and trends in thermal barrier and flame retardant nanocoatings.
  • Table 76. Nanomaterials utilized in thermal barrier and flame retardant coatings and benefits thereof.
  • Table 77. Thermal barrier and flame retardant nanocoatings-Markets, applications and potential addressable markets.
  • Table 78: Thermal barrier and flame retardant nanocoatings product and application developers.
  • Table 79. Market overview for anti-icing and de-icing nanocoatings.
  • Table 80. Market assessment for anti-icing and de-icing nanocoatings.
  • Table 81. Market drivers and trends for use of anti-icing and de-icing nanocoatings.
  • Table 82: Nanomaterials utilized in anti-icing coatings and benefits thereof.
  • Table 83. Anti-icing and de-icing nanocoatings-Markets, applications and potential addressable markets.
  • Table 84: Anti-icing and de-icing nanocoatings product and application developers.
  • Table 85: Anti-reflective nanocoatings-Nanomaterials used, principles, properties and applications.
  • Table 86. Market drivers and trends in Anti-reflective nanocoatings.
  • Table 87. Market opportunity for anti-reflection nanocoatings.
  • Table 88: Anti-reflective nanocoatings product and application developers.
  • Table 89. Market drivers and trends for nanocoatings in aviation and aerospace.
  • Table 90: Types of nanocoatings utilized in aerospace and application.
  • Table 91: Revenues for nanocoatings in the aerospace industry, 2010-2030.
  • Table 92: Aerospace nanocoatings product developers.
  • Table 93: Market drivers and trends for nanocoatings in the automotive market.
  • Table 94: Anti-scratch automotive nanocoatings.
  • Table 95: Conductive automotive nanocoatings.
  • Table 96: Hydro- and oleophobic automotive nanocoatings.
  • Table 97: Anti-corrosion automotive nanocoatings.
  • Table 98: UV-resistance automotive nanocoatings.
  • Table 99: Thermal barrier automotive nanocoatings.
  • Table 100: Flame retardant automotive nanocoatings.
  • Table 101: Anti-fingerprint automotive nanocoatings.
  • Table 102: Anti-bacterial automotive nanocoatings.
  • Table 103: Self-healing automotive nanocoatings.
  • Table 104: Revenues for nanocoatings in the automotive industry, 2010-2030, US$, conservative and optimistic estimate.
  • Table 105: Automotive nanocoatings product developers.
  • Table 106: Market drivers and trends for nanocoatings in the construction market.
  • Table 107: Nanocoatings applied in the construction industry-type of coating, nanomaterials utilized and benefits.
  • Table 108: Photocatalytic nanocoatings-Markets and applications.
  • Table 109: Revenues for nanocoatings in construction, architecture and exterior protection, 2010-2030, US$.
  • Table 110: Construction, architecture and exterior protection nanocoatings product developers.
  • Table 111: Market drivers for nanocoatings in electronics.
  • Table 112: Main companies in waterproof nanocoatings for electronics, products and synthesis methods.
  • Table 113: Conductive electronics nanocoatings.
  • Table 114: Anti-fingerprint electronics nanocoatings.
  • Table 115: Anti-abrasion electronics nanocoatings.
  • Table 116: Conductive electronics nanocoatings.
  • Table 117: Revenues for nanocoatings in electronics, 2010-2030, US$.
  • Table 118: Nanocoatings applications developers in electronics.
  • Table 119: Market drivers and trends for nanocoatings in household care and sanitary.
  • Table 120: Revenues for nanocoatings in household care, sanitary and indoor air quality, 2010-2030, US$.
  • Table 121: Household care, sanitary and indoor air quality nanocoatings product developers.
  • Table 122: Market drivers and trends for nanocoatings in the marine industry.
  • Table 123: Nanocoatings applied in the marine industry-type of coating, nanomaterials utilized and benefits.
  • Table 124: Revenues for nanocoatings in the marine sector, 2010-2030, US$.
  • Table 125: Marine nanocoatings product developers.
  • Table 126: Market drivers and trends for nanocoatings in medicine and healthcare.
  • Table 127: Nanocoatings applied in the medical industry-type of coating, nanomaterials utilized, benefits and applications.
  • Table 128: Types of advanced coatings applied in medical devices and implants.
  • Table 129: Nanomaterials utilized in medical implants.
  • Table 130: Revenues for nanocoatings in medical and healthcare, 2010-2030, US$.
  • Table 131: Medical and healthcare nanocoatings product developers.
  • Table 132: Market drivers and trends for nanocoatings in the military and defence industry.
  • Table 133: Revenues for nanocoatings in military and defence, 2010-2030, US$.
  • Table 134: Military and defence nanocoatings product and application developers.
  • Table 135: Market drivers and trends for nanocoatings in the packaging industry.
  • Table 136: Revenues for nanocoatings in packaging, 2010-2030, US$.
  • Table 137: Packaging nanocoatings companies.
  • Table 138: Market drivers and trends for nanocoatings in the textiles and apparel industry.
  • Table 139: Applications in textiles, by advanced materials type and benefits thereof.
  • Table 140: Nanocoatings applied in the textiles industry-type of coating, nanomaterials utilized, benefits and applications.
  • Table 141: Applications and benefits of graphene in textiles and apparel.
  • Table 142: Revenues for nanocoatings in textiles and apparel, 2010-2030, US$.
  • Table 143: Textiles nanocoatings product developers.
  • Table 144: Market drivers and trends for nanocoatings in the energy industry.
  • Table 145: Revenues for nanocoatings in energy, 2010-2030, US$.
  • Table 146: Renewable energy nanocoatings product developers.
  • Table 147: Market drivers and trends for nanocoatings in the oil and gas exploration industry.
  • Table 148: Desirable functional properties for the oil and gas industry afforded by nanomaterials in coatings.
  • Table 149: Revenues for nanocoatings in oil and gas exploration, 2010-2030, US$.
  • Table 150: Oil and gas nanocoatings product developers.
  • Table 151: Market drivers and trends for nanocoatings in tools and machining.
  • Table 152: Revenues for nanocoatings in Tools and manufacturing, 2010-2030, US$.
  • Table 153: Tools and manufacturing nanocoatings product and application developers.
  • Table 156. Photocatalytic coating schematic.
  • Table 158: Categorization of nanomaterials.

FIGURES

  • Figure 1: Global revenues for nanocoatings, 2010-2030, millions USD.
  • Figure 2: Regional demand for nanocoatings, 2019, millions USD.
  • Figure 3: Hydrophobic fluoropolymer nanocoatings on electronic circuit boards.
  • Figure 4: Nanocoatings synthesis techniques.
  • Figure 5: Techniques for constructing superhydrophobic coatings on substrates.
  • Figure 6: Electrospray deposition.
  • Figure 7: CVD technique.
  • Figure 8: Schematic of ALD.
  • Figure 9: SEM images of different layers of TiO2 nanoparticles in steel surface.
  • Figure 10: The coating system is applied to the surface.The solvent evaporates.
  • Figure 11: A first organization takes place where the silicon-containing bonding component (blue dots in figure 2) bonds covalently with the surface and cross-links with neighbouring molecules to form a strong three-dimensional.
  • Figure 12: During the curing, the compounds or- ganise themselves in a nanoscale monolayer. The fluorine-containing repellent component (red dots in figure 3) on top makes the glass hydro- phobic and oleophobic.
  • Figure 13: (a) Water drops on a lotus leaf.
  • Figure 14. A schematic of (a) water droplet on normal hydrophobic surface with contact angle greater than 90° and (b) water droplet on a superhydrophobic surface with a contact angle > 150°.
  • Figure 15: Contact angle on superhydrophobic coated surface.
  • Figure 16: SLIPS repellent coatings.
  • Figure 17: Omniphobic coatings.
  • Figure 18: Graphair membrane coating.
  • Figure 19: Antimicrobial activity of Graphene oxide (GO).
  • Figure 20: Conductive graphene coatings for rotor blades.
  • Figure 21: Water permeation through a brick without (left) and with (right) "graphene paint" coating.
  • Figure 22: Graphene heat transfer coating.
  • Figure 23 Carbon nanotube cable coatings.
  • Figure 24 Formation of a protective CNT-based char layer during combustion of a CNT-modified coating.
  • Figure 25. Mechanism of antimicrobial activity of carbon nanotubes.
  • Figure 26: Fullerene schematic.
  • Figure 27: Hydrophobic easy-to-clean coating.
  • Figure 28: Anti-fogging nanocoatings on protective eyewear.
  • Figure 29: Silica nanoparticle anti-reflection coating on glass.
  • Figure 30 Anti-bacterials mechanism of silver nanoparticle coating.
  • Figure 31: Mechanism of photocatalysis on a surface treated with TiO2 nanoparticles.
  • Figure 32: Schematic showing the self-cleaning phenomena on superhydrophilic surface.
  • Figure 33: Titanium dioxide-coated glass (left) and ordinary glass (right).
  • Figure 34: Self-Cleaning mechanism utilizing photooxidation.
  • Figure 35: Schematic of photocatalytic air purifying pavement.
  • Figure 36: Schematic of photocatalytic indoor air purification filter.
  • Figure 37: Schematic of photocatalytic water purification.
  • Figure 38. Schematic of antibacterial activity of ZnO NPs.
  • Figure 39: Types of nanocellulose.
  • Figure 40: CNF gel.
  • Figure 41: TEM image of cellulose nanocrystals.
  • Figure 42: Extracting CNC from trees.
  • Figure 43: An iridescent biomimetic cellulose multilayer film remains after water that contains cellulose nanocrystals evaporates.
  • Figure 44: CNC slurry.
  • Figure 45. TEM images of Burkholderia seminalis treated with (a, c) buffer (control) and (b, d) 2.0 mg/mL chitosan; (A: additional layer; B: membrane damage).
  • Figure 46: Anti-fingerprint nanocoating on glass.
  • Figure 47: Schematic of anti-fingerprint nanocoatings.
  • Figure 48: Toray anti-fingerprint film (left) and an existing lipophilic film (right).
  • Figure 49: Types of anti-fingerprint coatings applied to touchscreens.
  • Figure 50: Anti-fingerprint nanocoatings applications.
  • Figure 51: Revenues for anti-fingerprint nanocoatings, 2019-2030, adjusted for COVID-19 related demand, conservative and high estimates (millions USD).
  • Figure 52. Schematic of anti-viral coating using nano-actives for inactivation of any adhered virus on the surfaces.
  • Figure 53. Nano-coated self-cleaning touchscreen.
  • Figure 54: Revenues for Anti-microbial and anti-viral nanocoatings, 2019-2030, adjusted for COVID-19 related demand, conservative and high estimates (millions USD).
  • Figure 55: Nanovate CoP coating.
  • Figure 56: 2000 hour salt fog results for Teslan nanocoatings.
  • Figure 57: AnCatt proprietary polyaniline nanodispersion and coating structure.
  • Figure 58: Hybrid self-healing sol-gel coating.
  • Figure 59: Schematic of anti-corrosion via superhydrophobic surface.
  • Figure 60: Potential addressable market for anti-corrosion nanocoatings by 2030.
  • Figure 61: Revenues for anti-corrosion nanocoatings, 2019-2030, adjusted for COVID-19 related demand, conservative and high estimates (millions USD).
  • Figure 62: Revenues for abrasion and wear resistant nanocoatings, 2019-2030, adjusted for COVID-19 related demand, conservative and high estimates (millions USD).
  • Figure 63: Nanocomposite oxygen barrier schematic.
  • Figure 64: Schematic of barrier nanoparticles deposited on flexible substrates.
  • Figure 65: Revenues for barrier nanocoatings, 2019-2030, adjusted for COVID-19 related demand, conservative and high estimates (millions USD).
  • Figure 66: Anti-fouling treatment for heat-exchangers.
  • Figure 67: Removal of graffiti after application of nanocoating.
  • Figure 68: Potential addressable market for anti-fouling and easy-to-clean nanocoatings by 2030.
  • Figure 69: Revenues for anti-fouling and easy-to-clean nanocoatings, 2019-2030, adjusted for COVID-19 related demand, conservative and high estimates (millions USD).
  • Figure 70: Self-cleaning superhydrophobic coating schematic.
  • Figure 71: Potential addressable market for self-cleaning (bionic) nanocoatings by 2030.
  • Figure 72. Revenues for self-cleaning (bionic) nanocoatings, 2019-2030, US$, adjusted for COVID-19 related demand, conservative and high estimates
  • Figure 73. Schematic showing the self-cleaning phenomena on superhydrophilic surface.
  • Figure 74: Schematic of photocatalytic air purifying pavement.
  • Figure 75: Self-Cleaning mechanism utilizing photooxidation.
  • Figure 76: Photocatalytic oxidation (PCO) air filter.
  • Figure 77: Schematic of photocatalytic water purification.
  • Figure 78: Tokyo Station GranRoof. The titanium dioxide coating ensures long-lasting whiteness.
  • Figure 79: Potential addressable market for self-cleaning (photocatalytic) nanocoatings by 2030.
  • Figure 80. Revenues for self-cleaning (photocatalytic) nanocoatings, 2019-2030, US$, adjusted for COVID-19 related demand, conservative and high estimates
  • Figure 81: Markets for UV-resistant nanocoatings, %, 2019.
  • Figure 82: Potential addressable market for UV-resistant nanocoatings.
  • Figure 83: Revenues for UV-resistant nanocoatings, 2019-2030, adjusted for COVID-19 related demand, conservative and high estimates (millions USD).
  • Figure 84: Flame retardant nanocoating.
  • Figure 85: Markets for thermal barrier and flame retardant nanocoatings, %, 2019.
  • Figure 86: Potential addressable market for thermal barrier and flame retardant nanocoatings by 2030.
  • Figure 87: Revenues for thermal barrier and flame retardant nanocoatings, 2019-2030, adjusted for COVID-19 related demand, conservative and high estimates (millions USD).
  • Figure 88: Nanocoated surface in comparison to existing surfaces.
  • Figure 89: NANOMYTE® SuperAi, a Durable Anti-ice Coating.
  • Figure 90: SLIPS coating schematic.
  • Figure 91: Carbon nanotube based anti-icing/de-icing device.
  • Figure 92: CNT anti-icing nanocoating.
  • Figure 93: Potential addressable market for anti-icing and de-icing nanocoatings by 2030.
  • Figure 94: Revenues for anti-icing and de-icing nanocoatings, 2019-2030, adjusted for COVID-19 related demand, conservative and high estimates (millions USD).
  • Figure 95: Schematic of AR coating utilizing nanoporous coating.
  • Figure 96: Demo solar panels coated with nanocoatings.
  • Figure 97: Revenues for anti-reflective nanocoatings, 2019-2030, adjusted for COVID-19 related demand, conservative and high estimates (millions USD).
  • Figure 98 Nanocoatings market by end user sector, 2010-2030, USD.
  • Figure 99: Nanocoatings in the aerospace industry, by nanocoatings type %, 2019.
  • Figure 100: Potential addressable market for nanocoatings in aerospace by 2030.
  • Figure 101: Revenues for nanocoatings in the aerospace industry, 2010-2030, US$.
  • Figure 102: Nanocoatings in the automotive industry, by coatings type % 2019.
  • Figure 103: Potential addressable market for nanocoatings in the automotive sector by 2030.
  • Figure 104: Revenues for nanocoatings in the automotive industry, 2010-2030, US$.
  • Figure 105: Mechanism of photocatalytic NOx oxidation on active concrete road.
  • Figure 106: Jubilee Church in Rome, the outside coated with nano photocatalytic TiO2 coatings.
  • Figure 107: FN® photocatalytic coating, applied in the Project of Ecological Sound Barrier, in Prague.
  • Figure 108 Smart window film coatings based on indium tin oxide nanocrystals.
  • Figure 109: Nanocoatings in construction, architecture and exterior protection, by coatings type %, 2018.
  • Figure 110: Potential addressable market for nanocoatings in the construction, architecture and exterior coatings sector by 2030.
  • Figure 111: Revenues for nanocoatings in construction, architecture and exterior protection, 2010-2030, US$.
  • Figure 112: Reflection of light on anti-glare coating for display.
  • Figure 113: Nanocoating submerged in water.
  • Figure 114: Phone coated in WaterBlock submerged in water tank.
  • Figure 115: Self-healing patent schematic.
  • Figure 116: Self-healing glass developed at the University of Tokyo.
  • Figure 117: Royole flexible display.
  • Figure 118: Potential addressable market for nanocoatings in electronics by 2030.
  • Figure 119: Revenues for nanocoatings in electronics, 2010-2030, US$, conservative and optimistic estimates.
  • Figure 120: Nanocoatings in household care, sanitary and indoor air quality, by coatings type %, 2018.
  • Figure 121: Potential addressable market for nanocoatings in household care, sanitary and indoor air filtration by 2030.
  • Figure 122: Revenues for nanocoatings in household care, sanitary and indoor air quality, 2010-2030, US$.
  • Figure 123: Potential addressable market for nanocoatings in the marine sector by 2030.
  • Figure 124: Revenues for nanocoatings in the marine sector, 2010-2030, US$.
  • Figure 125: Anti-bacertial sol-gel nanoparticle silver coating.
  • Figure 126: Nanocoatings in medical and healthcare, by coatings type %, 2019.
  • Figure 127: Potential addressable market for nanocoatings in medical & healthcare by 2030.
  • Figure 128: Revenues for nanocoatings in medical and healthcare, 2010-2030, US$.
  • Figure 129: Nanocoatings in military and defence, by nanocoatings type %, 2018.
  • Figure 130: Potential addressable market nanocoatings in military and defence by 2030.
  • Figure 131: Revenues for nanocoatings in military and defence, 2010-2030, US$.
  • Figure 132: Nanocomposite oxygen barrier schematic.
  • Figure 133: Oso fresh food packaging incorporating antimicrobial silver.
  • Figure 134: Potential addressable market for nanocoatings in packaging by 2030.
  • Figure 135: Revenues for nanocoatings in packaging, 2010-2030, US$.
  • Figure 136: Omniphobic-coated fabric.
  • Figure 137: Work out shirt incorporating ECG sensors, flexible lights and heating elements.
  • Figure 138: Nanocoatings in textiles and apparel, by coatings type %, 2018.
  • Figure 139: Potential addressable market for nanocoatings in textiles and apparel by 2030.
  • Figure 140: Revenues for nanocoatings in textiles and apparel, 2010-2030, US$.
  • Figure 141: Self-Cleaning Hydrophobic Coatings on solar panels.
  • Figure 142: Znshine Graphene Series solar coatings.
  • Figure 143: Nanocoating for solar panels.
  • Figure 144: Nanocoatings in renewable energy, by coatings type %.
  • Figure 145: Potential addressable market for nanocoatings in renewable energy by 2030.
  • Figure 146: Revenues for nanocoatings in energy, 2010-2030, US$.
  • Figure 147: Oil-Repellent self-healing nanocoatings.
  • Figure 148: Nanocoatings in oil and gas exploration, by coatings type %.
  • Figure 149: Potential addressable market for nanocoatings in oil and gas exploration by 2030.
  • Figure 150: Revenues for nanocoatings in oil and gas exploration, 2010-2030, US$.
  • Figure 151: Revenues for nanocoatings in Tools and manufacturing, 2010-2030, US$.
  • Figure 154. Lab tests on DSP coatings.
  • Figure 155: Self-healing mechanism of SmartCorr coating.
  • Figure 156. GrapheneCA anti-bacterial and anti-viral coating.
  • Figure 157. Microlyte® Matrix bandage for surgical wounds.
  • Figure 158. Self-cleaning nanocoating applied to face masks.
  • Figure 160. NanoSeptic surfaces.
  • Figure 161. NascNanoTechnology personnel shown applying MEDICOAT to airport luggage carts.