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2014 Nanotechnology Research Review

REPORT HIGHLIGHTS

  • Global consumption of advanced and nanoscale ceramic powders will rise from $9 billion in 2013 to $12.1 billion in 2018, a compound annual growth rate (CAGR) of 6.2% over the next five years.
  • Global consumption of nanocomposites is expected to grow in unit terms from nearly 225,060 metric tons in 2014 to reach nearly 584,984 metric tons in 2019, a compound annual growth rate (CAGR) of 21.1% for the period of 2014 to 2019.
  • The global market for quantum dots (QDs) was estimated to generate $121.0 million in revenues in 2013. This market is expected to reach about $1.1 billion in 2016 and about $3.1 billion by 2018, at a compound annual growth rate (CAGR) of 90.8% for the five-year period, 2013 to 2018.

REPORT SCOPE

Research Reviews from BCC Research provide market professionals with concise market coverage within a specific research category. These Research Reviews include portions of several market research reports that were published in 2014, and are an efficient way for market professionals to keep up with the general market developments of 2014.

Please note that page references in the text are to pages in the original, complete report, and do not reflect the actual page numbers in this Research Review.

This 2014 Nanotechnology Research Review includes excerpts from the following reports:

  • NAN015G Advanced Ceramics and Nanoceramic Powders.
  • NAN021F Global Markets for Nanocomposites, Nanoparticles, Nanoclays, and Nanotubes.
  • NAN027D Quantum Dots: Global Market Growth and Future Commercial Prospects.
  • NAN045B Global Markets and Technologies for Nanofiltration.
  • NAN059A Nanotechnology in Printing: Global Markets.

We encourage you to obtain and benefit from the full market research reports that are excerpted in this Research Review.

BCC Research looks forward to serving your market intelligence needs in the future.

Table of Contents

CHAPTER 1 FOREWORD

CHAPTER 2 ADVANCED CERAMICS AND NANOCERAMIC POWDERS (REPORT NAN015G)

  • INTRODUCTION
  • STUDY GOALS AND OBJECTIVES
  • CONTRIBUTIONS OF THE STUDY
  • SCOPE OF REPORT
  • METHODOLOGY AND INFORMATION SOURCES
  • INTENDED AUDIENCE
  • ANALYST'S CREDENTIALS
  • RELATED BCC RESEARCH REPORTS
  • EXECUTIVE SUMMARY
  • TABLE 1 GLOBAL CONSUMPTION OF ADVANCED AND NANOSCALE CERAMIC POWDERS, THROUGH 2018 (MILLION LBS/$ MILLIONS)
  • FIGURE 1 GLOBAL CONSUMPTION OF ADVANCED AND NANOSIZED CERAMIC POWDERS, 2012-2018 (% OF TOTAL VALUE CONSUMED)
  • OVERVIEW
  • TABLE 2 COMMONLY USED ADVANCED CERAMIC MATERIAL FAMILIES
  • ADVANCED CERAMIC POWDER MANUFACTURING
  • R&D SCALE PROCESSES
    • THERMAL DECOMPOSITION
    • CHEMICAL VAPOR DEPOSITION (CVD)
    • PLASMA PROCESSES
    • TABLE 3 PLASMA SYNTHESIS OF CERAMIC POWDERS
    • FIGURE 2 SCHEMATIC OF DC ARC PLASMA FURNACE DEVELOPED BY THE JAPAN NATIONAL RESEARCH INSTITUTE FOR METALS
    • FIGURE 3 LOS ALAMOS RF PLASMA REACTOR
    • SOL-GEL TECHNIQUES
    • PRECIPITATION
    • HYDROTHERMAL SYNTHESIS
    • EMULSION PROCESS
    • FIGURE 4 PROCESS FLOWCHART FOR EMULSION PROCESS TO PRODUCE BARIUM TITANATE
    • LASER SYNTHESIS
    • COMBUSTION SYNTHESIS/SELF-PROPAGATING HIGH-TEMPERATURE SYNTHESIS
    • COMBINATORIALLY DISCOVERED MATERIALS
      • Powder Synthesis Comparison
      • TABLE 4 POWDER SYNTHESIS COMPARISON
      • TABLE 5 POWDER PROCESSES FOR VARIOUS CERAMIC MATERIALS
  • MATERIAL APPLICATIONS AND PROPERTIES
    • STRUCTURAL CERAMICS
    • ELECTRONIC CERAMICS
    • CERAMIC COATINGS
    • CHEMICAL AND ENVIRONMENTAL CONTROL RELATED
    • TABLE 6 CURRENT AND POTENTIAL USES FOR ADVANCED CERAMICS
  • ADVANCED STRUCTURAL CERAMICS
  • TABLE 7 CURRENT AND POTENTIAL APPLICATIONS OF ADVANCED STRUCTURAL CERAMICS
    • MONOLITHIC STRUCTURAL CERAMICS
    • TABLE 8 PROPERTIES OF COMMERCIAL ALUMINA
    • TABLE 9 PROPERTIES OF NORZIDE YZ-110HS TETRAGONAL ZIRCONIA CERAMIC
    • TABLE 10 FRACTURE TOUGHNESS AND CRITICAL FLAW SIZES OF MONOLITHIC AND COMPOSITE CERAMIC MATERIALS
    • TABLE 11 PROPERTIES OF MONOLITHIC CERAMICS AND CERAMIC COMPOSITES
    • TABLE 12 THERMAL CONDUCTIVITY OF VARIOUS ZIRCONIAS
  • CERAMIC MATRIX COMPOSITES
    • CERAMIC COATINGS
    • TABLE 13 HIGH-PERFORMANCE CERAMIC COATING MATERIALS AND GENERAL APPLICATIONS
    • TABLE 14 REPRESENTATIVE FLAME AND PLASMA SPRAYED MATERIALS, MELTING OR SOFTENING TEMPERATURES AND APPLICATIONS
    • ELECTRONIC CERAMICS
    • INSULATORS
    • TABLE 15 CERAMIC INSULATORS AND THEIR PROPERTIES
    • SUBSTRATES, IC PACKAGES AND MULTICHIP MODULES
    • TABLE 16 CERAMIC SUBSTRATE PROPERTIES
    • TABLE 17 CANDIDATE CERAMIC SUBSTRATE MATERIALS FOR ELECTRONICS

CHAPTER 3 GLOBAL MARKETS FOR NANOCOMPOSITES, NANOPARTICLES, NANOCLAYS, AND NANOTUBES (REPORT NAN021F)

  • STUDY BACKGROUND
  • STUDY GOALS AND OBJECTIVES
  • INTENDED AUDIENCE
  • SCOPE AND FORMAT
  • METHODOLOGY AND INFORMATION SOURCES
  • ANALYST'S CREDENTIALS
  • RELATED BCC RESEARCH REPORTS
  • EXECUTIVE SUMMARY
  • TABLE 18 GLOBAL CONSUMPTION OF NANOCOMPOSITES, THROUGH 2019 (MT/$ MILLIONS)
  • FIGURE 5 GLOBAL CONSUMPTION OF NANOCOMPOSITES, 2013-2019 ($ MILLIONS)
  • NANOCOMPOSITES OVERVIEW AND GENERAL DESCRIPTIONS
    • DEFINITIONS
      • Composites
      • Nanocomposites
        • Fillers vs. Matrix Materials
    • BRIEF HISTORY OF NANOCOMPOSITES
  • GENERAL PROPERTIES OF NANOCOMPOSITES VS. CONVENTIONAL COMPOSITES
    • INCREASED TENSILE STRENGTH, MODULUS, AND HEAT DISTORTION TEMPERATURE
    • COLOR/TRANSPARENCY
    • CONDUCTIVITY
    • FLAME RETARDANCY
    • BARRIER PROPERTIES
    • ANTICORROSIVE PROPERTIES
  • TYPES OF NANOCOMPOSITES, THEIR PROPERTIES AND APPLICATIONS
    • CLAY NANOCOMPOSITES
      • Materials
        • Clay Fillers
          • Natural Clays
            • Montmorillonite
            • Vermiculite
            • Octosilicate
            • Bentonite
            • Hectorite
            • Halloysite 4
          • Synthetic Clays
            • Fluorohectorite
            • Hydrotalcite
            • Laponite
        • Matrix Materials
          • Nylon
          • Butyl
          • Thermoplastic Olefins
          • Polyethylene
          • Polypropylene
          • Polyvinyl Chloride
          • Ethylene Vinyl Acetate
          • Other Matrix Materials
            • Polyethylene Terephthalate
            • Acetal
            • Polychloroprene
            • Nitrile Rubber
            • Ethylene Vinyl Alcohol
      • Fabrication
        • Production and Pre-Treatment of Clay Filler Materials
        • Compounding
        • Types of Clay Nanocomposites
        • Commercial Clay Nanocomposites
        • TABLE 19 PROPERTIES AND MAIN APPLICATIONS OF PRINCIPAL TYPES OF COMMERCIAL CLAY NANOCOMPOSITES
          • Nylon/Montmorillonite
            • Automotive Applications
            • Packaging Applications
            • Life Sciences Applications
          • TPO/Montmorillonite
            • Automotive Applications
          • EVA/Montmorillonite
            • Flame-retardant Applications
          • Polypropylene/Montmorillonite
            • Automotive Applications
            • Fire-retardant Applications
            • Other Applications
          • Polyethylene/Montmorillonite
            • Packaging Applications
            • Automotive Applications
          • Acetal/Montmorillonite
          • Nylon/Mica Fluoride
            • Automotive Applications
          • Butyl/Vermiculite
            • Consumer Products Applications
            • Other Applications
        • Other Polymer/Clay Nanocomposites under Development
        • TABLE 20 OTHER CLAY NANOCOMPOSITES
          • PET/Montmorillonite
          • EVOH/Montmorillonite
          • Other Matrix Materials/Vermiculite
      • Applications
      • TABLE 21 PRINCIPAL APPLICATIONS OF CLAY CONTAINING COMPOSITES
        • Automotive
        • Packaging
        • Healthcare
        • Consumer Products
        • Flame-retardants
      • Suppliers
      • TABLE 22 CLAY NANOCOMPOSITE SUPPLIERS
    • CERAMIC NANOCOMPOSITES
      • Materials
        • Ceramic Fillers
          • Silica
          • Alumina
          • Zirconia
          • Tungsten Carbide
          • Organosilicates
        • Matrix Materials
          • Polymer Matrix Materials
            • Polyurethane
          • Epoxy
        • Metals and Metal Oxides
          • Titanium Dioxide
          • Cobalt
        • Other Materials
          • Calcium Phosphate
        • Fabrication
        • Inorganic Moiety-Containing Monomers
        • In Situ Fabrication of Ceramic Nanocomposite Films
        • Fabrication of WC/Co Nanocomposite Aggregates
      • Types and Properties
      • TABLE 23 PROPERTIES AND MAIN APPLICATIONS FOR PRINCIPAL TYPES OF CERAMIC-CONTAINING NANOCOMPOSITES
        • Polyurethane/Alumina
        • Titanium Dioxide/Alumina
        • Alumina/Zirconia
        • Epoxy/Carbon Fiber/Silica
        • Polyurethane/Organosilica
        • Cobalt/Tungsten Carbide
        • Calcium Phosphate/Silica
        • PET-Oxynitride
      • Applications
      • TABLE 24 PRINCIPAL APPLICATIONS OF CERAMIC CONTAINING COMPOSITES
        • Coating Applications
          • Floor Finishes
          • Thermal Spray Coatings
          • Window Coatings
        • Life Sciences
          • Hip Implants
          • Artificial Spinal Disks
          • Bone Replacements and Cements
        • Consumer Products
          • Tennis Racquets
        • Other Applications
          • Cutting Tools, Wear Parts
      • Suppliers
      • TABLE 25 CERAMIC NANOCOMPOSITE SUPPLIERS
    • CARBON NANOTUBE COMPOSITES
      • Materials
        • Fillers
          • Carbon Nanotubes
          • Fullerenes
          • Carbon Nanofibers
          • Graphene
        • Matrix Materials
        • Polymers
          • Polycarbonate
          • Polybutylene Terephthalate
          • Polyphenyl Ether
      • Fabrication Technologies
        • Oriented Nanocomposite Extrusion Process
        • Layered Fabrication
        • CNT Fibers
      • Types of Carbon Nanotube Composites
      • TABLE 26 PROPERTIES OF CARBON NANOTUBE COMPOSITE
        • Nylon/MWNT Composites
        • Polycarbonate/MWNT Composites
        • Polyvinyl Alcohol/MWNT Composites
        • Polybutylene Terephthalate/MWNT Composites
        • Polyphenylene Ether/Polyamide/MWNT Composites
        • Epoxy/MWNT/Carbon Fiber Composites
        • Polyurethane/Fullerene Composites
        • MDMO-PPV/Fullerene
      • Applications
      • TABLE 27 PRINCIPAL APPLICATIONS OF NANOTUBE COMPOSITES

CHAPTER 4 QUANTUM DOTS: GLOBAL MARKET GROWTH AND FUTURE COMMERCIAL PROSPECTS (REPORT NAN027D)

  • INTRODUCTION
  • STUDY GOAL AND OBJECTIVES
  • SCOPE AND FORMAT
  • CONTRIBUTIONS OF THE STUDY AND TARGET AUDIENCE
  • METHODOLOGY AND SOURCES OF INFORMATION
  • ABOUT THE AUTHOR
  • RELATED BCC RESEARCH REPORTS
  • EXECUTIVE SUMMARY
  • TABLE 28 GLOBAL MARKET REVENUES FOR QUANTUM DOTS BY MARKET SECTOR, THROUGH 2018 ($ MILLIONS)
  • FIGURE 6 TOTAL GLOBAL MARKET REVENUE FOR QD-BASED PRODUCTS, 2013-2018 ($ MILLIONS)
  • TECHNOLOGY OVERVIEW
  • WHAT IS A QUANTUM DOT?
  • HISTORY OF QUANTUM DOTS
  • TABLE 29 CHRONOLOGICAL EVOLUTION OF QDS: FROM RESEARCH CURIOSITY THROUGH TO COMMERCIAL DEVELOPMENT
  • PROPERTIES OF QUANTUM DOTS
  • FIGURE 7 LUMINESCENCE SIZE REGIMES FOR DIFFERENT SEMICONDUCTOR AND METAL QUANTUM DOTS
  • TABLE 30 COMPARISON OF EMISSION WAVELENGTH OF SC AND METAL NC QUANTUM DOTS AS A FUNCTION OF THEIR SIZE
  • TABLE 31 OTHER PROPERTIES OF COLLOIDAL QUANTUM DOTS
  • QUANTUM DOT INDUSTRY
  • APPLICATIONS AND STRUCTURAL TYPES OF QUANTUM DOTS
    • BASIC STRUCTURES
    • TABLE 32 HIERARCHY AND VARIOUS TYPES OF QDS: BASIC STRUCTURES
    • COMPOSITE STRUCTURES
    • TABLE 33 HIERARCHY AND VARIOUS TYPES OF QDS: COMPOSITE STRUCTURES
    • COMMERCIAL APPLICATIONS
    • TABLE 34 QD MATERIAL TYPES AND THEIR COMMERCIAL APPLICATIONS
    • TABLE 35 KEY QUANTUM DOT TECHNOLOGIES AND APPLICATIONS
    • PATENT ANALYSIS
  • QUANTUM DOT PRODUCTION (SYNTHESIS) AND DEVICE ASSEMBLY
  • SYNTHESIS OF METAL CHALCOGENIDE QUANTUM DOTS
    • VAPOR PHASE
    • TABLE 36 QUANTUM DOT PRODUCTION METHODS: VAPOR PHASE
      • Aerosol Drop Method
      • Melt Atomization
      • Chemical Vapor Deposition
      • Physical Vapor Deposition
      • Molecular Beam Epitaxy
    • LIQUID PHASE ("WET" COLLOID CHEMISTRY)
    • TABLE 37 QUANTUM DOT PRODUCTION METHODS: LIQUID PHASE
      • Colloid
        • Batch Process
        • Continuous Flow
      • Precipitation
    • SOLID PHASE
    • TABLE 38 QUANTUM DOT PRODUCTION METHODS: SOLID PHASE
  • SYNTHESIS OF NANOCRYSTALLINE SILICON QDS
    • LIQUID PHASE SYNTHESIS
    • TABLE 39 VARIOUS METHODS USED FOR SI-NC SYNTHESIS
    • SOLID-PHASE SYNTHESIS
    • VAPOR-PHASE SYNTHESIS
  • SYNTHESIS OF NANOCRYSTALLINE METALS BASED QDS
  • TABLE 40 VARIOUS SYNTHETIC METHODS AND PHOTOPHYSICAL BEHAVIOR OF METAL-NCS
  • SYNTHESIS OF CARBON NANOMATERIAL-BASED QUANTUM DOTS
    • CARBON QUANTUM DOTS
    • GRAPHENE QUANTUM DOTS
  • ASSEMBLY OF QUANTUM DOT STRUCTURES
  • TABLE 41 QUANTUM DOT STRUCTURE ASSEMBLY METHODS
    • LITHOGRAPHY
      • Conventional Top-Down Methods
      • Nanolithography
    • FILM FORMATION
      • Cast Film
      • Langmuir-Blodgett
        • Layer-by-Layer
      • Metamaterials
      • Biomolecular Self-Assembly
      • Photopatternable Arrays
    • OTHER TECHNIQUES
      • Digital Printing
      • Nanoporous Templates
  • QUANTUM DOT APPLICATIONS AND END USES 123
  • TABLE 42 MAIN APPLICATION SECTORS AND INDUSTRIAL END USES IDENTIFIED FOR QUANTUM DOT TECHNOLOGY
    • BIOMEDICAL
    • ELECTRONICS
    • OPTICS
    • OPTOELECTRONICS
    • SECURITY
    • SUSTAINABLE ENERGY
  • MARKET SECTORIZATION AND FIVE-YEAR REVENUE GROWTH TRENDS
  • TABLE 43 GLOBAL MARKET REVENUE GENERATED BY QUANTUM DOTS ACCORDING TO MAJOR MARKET SECTORS, THROUGH 2018 ($ MILLIONS)
  • FIGURE 8 GLOBAL MARKET REVENUES GENERATED BY QUANTUM DOTS ACCORDING TO MAJOR MARKET SECTORS, 2013 AND 2018 ($ MILLIONS)

CHAPTER 5 GLOBAL MARKETS AND TECHNOLOGIES FOR NANOFILTRATION (REPORT NAN045B)

  • INTRODUCTION, STUDY GOALS AND OBJECTIVES
  • REASONS FOR DOING THIS STUDY
  • INTENDED AUDIENCE
  • SCOPE OF REPORT
  • METHODOLOGY AND INFORMATION SOURCES
  • RELATED BCC RESEARCH REPORTS
  • ANALYST'S CREDENTIALS
  • EXECUTIVE SUMMARY
  • TABLE 44 GLOBAL MARKET FOR NANOFILTRATION MEMBRANES, THROUGH 2019 ($ MILLIONS)
  • FIGURE 9 GLOBAL MARKET FOR NANOFILTRATION MEMBRANES, 2012-2019 ($ MILLIONS)
  • OVERVIEW OF MEMBRANE-BASED SEPARATION PROCESSES AND NANOFILTRATION
  • TABLE 45 MEMBRANE-BASED SEPARATION PROCESSES, 2014
    • THE MEMBRANE INDUSTRY
    • TABLE 46 MEMBRANE MARKET BY REGION, THROUGH 2018 ($ MILLIONS)
    • TABLE 47 APPLICATIONS OF MEMBRANE-BASED SEPARATION PROCESSES, 2014
    • NANOFILTRATION
    • TABLE 48 MICROFILTRATION, ULTRAFILTRATION, NANOFILTRATION AND REVERSE OSMOSIS MEMBRANE PROPERTIES
  • MILESTONES IN THE HISTORY OF NANOFILTRATION AND RECENT EVENTS
  • TABLE 49 MEMBRANE SEPARATION PROCESSES AND NANOFILTRATION-TECHNOLOGICAL MILESTONES
  • FIGURE 10 NANOFILTRATION: WORLDWIDE PATENT APPLICATIONS AND PATENTS ISSUED SINCE 1970, BY DECADE (NO. OF PATENTS)
  • TABLE
    • APPLICATIONS OF NANOFILTRATION
    • TABLE 50 APPLICATIONS OF NANOFILTRATION, 2014
    • WATER AND WASTEWATER TREATMENT
      • Potable Water
      • Desalination of Brackish Water and Seawater
        • Dual-Stage Filtration
      • Wastewater
    • FOOD INDUSTRY
      • Dairy Industry
      • Beverages
      • Others
    • CHEMICAL AND PETROCHEMICAL INDUSTRY
      • Treatment of Acid and Caustic Solutions
      • Recovery and Recycle of Catalysts
      • Organic Solvent Nanofiltration
      • Oil/Water Separation
      • Oil and Gas Processing
      • Production of Lactic Acid
    • METAL WORKING INDUSTRY
    • PHARMACEUTICAL AND BIOMEDICAL INDUSTRY
    • OTHERS

CHAPTER 6 NANOTECHNOLOGY IN PRINTING: GLOBAL MARKETS (REPORT NAN059A)

  • INTRODUCTION, STUDY GOALS AND OBJECTIVES
  • REASONS FOR DOING THE STUDY
  • SCOPE OF REPORT
  • INTENDED AUDIENCE
  • INFORMATION SOURCES
  • ANALYST'S CREDENTIALS
  • RELATED BCC RESEARCH REPORTS
  • MARKET SUMMARY
  • TABLE 51 CONSOLIDATED GLOBAL MARKET FOR NANOTECHNOLOGY-ENABLED PRINTING BY REGION, THROUGH 2018 ($ MILLIONS)
  • FIGURE 11 CONSOLIDATED GLOBAL MARKET FOR NANOTECHNOLOGY-ENABLED PRINTING BY REGION, 2011-2018 ($ MILLIONS)
  • INDUSTRY DEFINITION
  • SCOPE OF THE INDUSTRY
  • MARKET POTENTIAL FOR NANOTECHNOLOGY-ENABLED PRINTING
  • CONCEPT OF NANOTECHNOLOGY
  • FOUR GENERATIONS OF NANOTECHNOLOGY
  • TABLE 52 FOUR GENERATIONS OF NANOTECHNOLOGY
  • ROLE OF NANOTECHNOLOGY IN PRINTING INDUSTRY
  • COMMON KEY WORDS USED IN NANOTECHNOLOGY-ENABLED PRINTING
    • NANOTECHNOLOGY
    • NANOMATERIALS
      • Nanoparticles
      • Quantum Dots
      • Carbon Nanotubes
      • Nanowires
      • Graphene
    • PRINTING
    • SINTERING PROCESS
    • PATTERN
    • SUBSTRATE
    • NANOLITHOGRAPHY
    • NEXT GENERATION LITHOGRAPHY
    • SOFT LITHOGRAPHY
    • INKJET PRINTING
    • SEMICONDUCTOR
    • SEMICONDUCTOR DEVICE FABRICATION
    • SEMICONDUCTOR FOUNDRY
  • KEY AREAS WHERE NANOTECHNOLOGY IN PRINTING IS USED
    • PRINTING ELECTRONICS
    • CONDUCTIVE INKS FOR PRINTING ELECTRONICS
    • APPLICATIONS OF CONDUCTIVE INKS AND ROLE OF NANOTECHNOLOGY
      • Printing RFID Tags and Sensors in Smart Packaging
      • Printing Solar/Photovoltaic Cells
      • Printing Organic/Light Emitting Diode (O/LED)
    • INVISIBLE INKS FOR PRINTING SECURITY DOCUMENTS, ANTI-COUNTERFEITING
    • FABRICATING SEMICONDUCTORS
    • OTHER NOVEL APPLICATIONS
  • ADVANTAGES OF NANOTECHNOLOGY IN PRINTING
    • NANOMATERIALS PROVIDE INCREASED CONDUCTIVITY
    • NANOMATERIAL-ENABLED PRINTING ON A VARIETY OF THIN AND FLEXIBLE SUBSTRATES
    • POSSIBLE PRODUCTION OF NANOSTRUCTURE TRANSISTORS
    • DEVELOPMENT OF MINIATURE STRUCTURES USING 3D PRINTING

LIST OF TABLES

  • TABLE 1 GLOBAL CONSUMPTION OF ADVANCED AND NANOSCALE CERAMIC POWDERS, THROUGH 2018 (MILLION LBS/$ MILLIONS)
  • TABLE 2 COMMONLY USED ADVANCED CERAMIC MATERIAL FAMILIES
  • TABLE 3 PLASMA SYNTHESIS OF CERAMIC POWDERS
  • TABLE 4 POWDER SYNTHESIS COMPARISON
  • TABLE 5 POWDER PROCESSES FOR VARIOUS CERAMIC MATERIALS
  • TABLE 6 CURRENT AND POTENTIAL USES FOR ADVANCED CERAMICS
  • TABLE 7 CURRENT AND POTENTIAL APPLICATIONS OF ADVANCED STRUCTURAL CERAMICS
  • TABLE 8 PROPERTIES OF COMMERCIAL ALUMINA
  • TABLE 9 PROPERTIES OF NORZIDE YZ-110HS TETRAGONAL ZIRCONIA CERAMIC
  • TABLE 10 FRACTURE TOUGHNESS AND CRITICAL FLAW SIZES OF MONOLITHIC AND COMPOSITE CERAMIC MATERIALS
  • TABLE 11 PROPERTIES OF MONOLITHIC CERAMICS AND CERAMIC COMPOSITES
  • TABLE 12 THERMAL CONDUCTIVITY OF VARIOUS ZIRCONIAS
  • TABLE 13 HIGH-PERFORMANCE CERAMIC COATING MATERIALS AND GENERAL APPLICATIONS
  • TABLE 14 REPRESENTATIVE FLAME AND PLASMA SPRAYED MATERIALS, MELTING OR SOFTENING TEMPERATURES AND APPLICATIONS
  • TABLE 15 CERAMIC INSULATORS AND THEIR PROPERTIES
  • TABLE 16 CERAMIC SUBSTRATE PROPERTIES
  • TABLE 17 CANDIDATE CERAMIC SUBSTRATE MATERIALS FOR ELECTRONICS
  • TABLE 18 GLOBAL CONSUMPTION OF NANOCOMPOSITES, THROUGH 2019 (MT/$ MILLIONS)
  • TABLE 19 PROPERTIES AND MAIN APPLICATIONS OF PRINCIPAL TYPES OF COMMERCIAL CLAY NANOCOMPOSITES
  • TABLE 20 OTHER CLAY NANOCOMPOSITES
  • TABLE 21 PRINCIPAL APPLICATIONS OF CLAY CONTAINING COMPOSITES
  • TABLE 22 CLAY NANOCOMPOSITE SUPPLIERS
  • TABLE 23 PROPERTIES AND MAIN APPLICATIONS FOR PRINCIPAL TYPES OF CERAMIC-CONTAINING NANOCOMPOSITES
  • TABLE 24 PRINCIPAL APPLICATIONS OF CERAMIC CONTAINING COMPOSITES
  • TABLE 25 CERAMIC NANOCOMPOSITE SUPPLIERS
  • TABLE 26 PROPERTIES OF CARBON NANOTUBE COMPOSITE
  • TABLE 27 PRINCIPAL APPLICATIONS OF NANOTUBE COMPOSITES
  • TABLE 28 GLOBAL MARKET REVENUES FOR QUANTUM DOTS BY MARKET SECTOR, THROUGH 2018 ($ MILLIONS)
  • TABLE 29 CHRONOLOGICAL EVOLUTION OF QDS: FROM RESEARCH CURIOSITY THROUGH TO COMMERCIAL DEVELOPMENT
  • TABLE 30 COMPARISON OF EMISSION WAVELENGTH OF SC AND METAL NC QUANTUM DOTS AS A FUNCTION OF THEIR SIZE
  • TABLE 31 OTHER PROPERTIES OF COLLOIDAL QUANTUM DOTS
  • TABLE 32 HIERARCHY AND VARIOUS TYPES OF QDS: BASIC STRUCTURES
  • TABLE 33 HIERARCHY AND VARIOUS TYPES OF QDS: COMPOSITE STRUCTURES
  • TABLE 34 QD MATERIAL TYPES AND THEIR COMMERCIAL APPLICATIONS
  • TABLE 35 KEY QUANTUM DOT TECHNOLOGIES AND APPLICATIONS
  • TABLE 36 QUANTUM DOT PRODUCTION METHODS: VAPOR PHASE
  • TABLE 37 QUANTUM DOT PRODUCTION METHODS: LIQUID PHASE
  • TABLE 38 QUANTUM DOT PRODUCTION METHODS: SOLID PHASE
  • TABLE 39 VARIOUS METHODS USED FOR SI-NC SYNTHESIS
  • TABLE 40 VARIOUS SYNTHETIC METHODS AND PHOTOPHYSICAL BEHAVIOR OF METAL-NCS
  • TABLE 41 QUANTUM DOT STRUCTURE ASSEMBLY METHODS
  • TABLE 42 MAIN APPLICATION SECTORS AND INDUSTRIAL END USES IDENTIFIED FOR QUANTUM DOT TECHNOLOGY
  • TABLE 43 GLOBAL MARKET REVENUE GENERATED BY QUANTUM DOTS ACCORDING TO MAJOR MARKET SECTORS, THROUGH 2018 ($ MILLIONS)
  • TABLE 44 GLOBAL MARKET FOR NANOFILTRATION MEMBRANES, THROUGH 2019 ($ MILLIONS)
  • TABLE 45 MEMBRANE-BASED SEPARATION PROCESSES, 2014
  • TABLE 46 MEMBRANE MARKET BY REGION, THROUGH 2018 ($ MILLIONS)
  • TABLE 47 APPLICATIONS OF MEMBRANE-BASED SEPARATION PROCESSES, 2014
  • TABLE 48 MICROFILTRATION, ULTRAFILTRATION, NANOFILTRATION AND REVERSE OSMOSIS MEMBRANE PROPERTIES
  • TABLE 49 MEMBRANE SEPARATION PROCESSES AND NANOFILTRATION-TECHNOLOGICAL MILESTONES
  • TABLE 50 APPLICATIONS OF NANOFILTRATION, 2014
  • TABLE 51 CONSOLIDATED GLOBAL MARKET FOR NANOTECHNOLOGY-ENABLED PRINTING BY REGION, THROUGH 2018 ($ MILLIONS)
  • TABLE 52 FOUR GENERATIONS OF NANOTECHNOLOGY

LIST OF FIGURES

  • FIGURE 1 GLOBAL CONSUMPTION OF ADVANCED AND NANOSIZED CERAMIC POWDERS, 2012-2018 (% OF TOTAL VALUE CONSUMED)
  • FIGURE 2 SCHEMATIC OF DC ARC PLASMA FURNACE DEVELOPED BY THE JAPAN NATIONAL RESEARCH INSTITUTE FOR METALS
  • FIGURE 3 LOS ALAMOS RF PLASMA REACTOR
  • FIGURE 4 PROCESS FLOWCHART FOR EMULSION PROCESS TO PRODUCE BARIUM TITANATE
  • FIGURE 5 GLOBAL CONSUMPTION OF NANOCOMPOSITES, 2013-2019 ($ MILLIONS)
  • FIGURE 6 TOTAL GLOBAL MARKET REVENUE FOR QD-BASED PRODUCTS, 2013-2018 ($ MILLIONS)
  • FIGURE 7 LUMINESCENCE SIZE REGIMES FOR DIFFERENT SEMICONDUCTOR AND METAL QUANTUM DOTS
  • FIGURE 8 GLOBAL MARKET REVENUES GENERATED BY QUANTUM DOTS ACCORDING TO MAJOR MARKET SECTORS, 2013 AND 2018 ($ MILLIONS)
  • FIGURE 9 GLOBAL MARKET FOR NANOFILTRATION MEMBRANES, 2012-2019 ($ MILLIONS)
  • FIGURE 10 NANOFILTRATION: WORLDWIDE PATENT APPLICATIONS AND PATENTS ISSUED SINCE 1970, BY DECADE (NO. OF PATENTS)
  • FIGURE 11 CONSOLIDATED GLOBAL MARKET FOR NANOTECHNOLOGY-ENABLED PRINTING BY REGION, 2011-2018 ($ MILLIONS)
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