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1. | EXECUTIVE SUMMARY AND CONCLUSIONS |
1.1. | Graphene - Introduction |
1.2. | Advanced Carbon: Overview |
1.3. | Understanding Graphene: Production process |
1.4. | Understanding Graphene: Material grades & forms |
1.5. | Does anyone mass produce true graphene? |
1.6. | Not all graphenes are equal: benchmarking study |
1.7. | What is the next generation of graphene? |
1.8. | The hype curve of the graphene industry |
1.9. | Market entry from major players |
1.10. | IP and regulatory landscape |
1.11. | Comparison of business models |
1.12. | Supply chain for GNP/rGO enabled polymer product |
1.13. | Market leaders emerge and consolidation anticipated |
1.14. | Private graphene investments |
1.15. | Mergers and acquisitions |
1.16. | Value creation for graphene companies: a look at public valuation trends |
1.17. | Revenue of graphene companies |
1.18. | Profit and loss trend of graphene companies |
1.19. | Profitable graphene companies |
1.20. | Graphite players see opportunity in graphene |
1.21. | Graphene platelet-type: global production capacity |
1.22. | The rise of China in graphene? |
1.23. | The importance of intermediaries |
1.24. | Is graphene green? |
1.25. | Graphene prices by suppliers |
1.26. | Is there a commoditization risk for the graphene? |
1.27. | Overview of Graphene Manufacturers |
1.28. | Main graphene oxide manufacturers |
1.29. | Graphene in China |
1.30. | Main Chinese manufacturers |
1.31. | Learning from the capacity progression of MWCNTs |
1.32. | CVD graphene manufacturers |
1.33. | Graphene film production - technical challenges remain |
1.34. | CVD graphene - applications are shifting |
1.35. | Expanding graphene wafer capacity and adoption |
1.36. | Application Overview - GNP and rGO |
1.37. | Competitive Landscape - Application |
1.38. | Graphene applications going commercial? |
1.39. | Market breakdown by revenue and volume |
1.40. | Commercial Indicators of the inflection point |
1.41. | Nanoinformatics - Accelerating R&D |
1.42. | Overview of 2D materials beyond graphene |
1.43. | Company Profiles |
2. | MARKET FORECASTS |
2.1. | Forecast methodology and assumptions |
2.2. | Granular ten year graphene market forecast segmented by 18 application areas |
2.3. | Ten-year forecast for volume (MT) demand for graphene material |
2.4. | Progression of the graphene market |
2.5. | Ten-year forecast for graphene platelet vs sheets |
2.6. | CNT market forecast comparison |
2.7. | Assessment of TAMs |
3. | COMPETITIVE MATERIAL LANDSCAPE |
3.1. | Advanced Carbon: Overview |
3.2. | Carbon Black - Overview |
3.3. | Specialty Carbon Black Analysis |
3.4. | Carbon Nanotubes - Overview |
3.5. | Progression and Outlook for MWCNT Capacity |
3.6. | Graphite - Overview |
3.7. | Carbon Fiber - Overview |
3.8. | Incumbent material - graphene competition |
4. | PATENT TRENDS |
4.1. | Graphene Patent Trends |
4.2. | Top Patent Holders: Dominance of Asia is Clear |
4.3. | Key Historic Patent and New Entrants |
4.4. | Graphene patent classification |
4.5. | Geographic Patent Distribution and Outlook |
5. | GRAPHENE PRODUCTION |
5.1. | Explaining the main graphene manufacturing routes |
5.2. | Quality and consistency issue |
5.3. | Expanded graphite |
5.4. | Reduced graphene oxide |
5.5. | Oxidising graphite: processes and characteristics |
5.6. | Reducing graphene oxide: different methods |
5.7. | Direct liquid phase exfoliation: process and characteristics |
5.8. | Direct liquid phase exfoliation under shear force |
5.9. | Electrochemical exfoliation |
5.10. | Properties of electrochemical exfoliated graphene |
5.11. | Plasma exfoliation |
5.12. | Increasing number of plasma processes |
5.13. | Substrate-less CVD (chemical vapour deposition) |
5.14. | Substrate-less CVD: growth of flower like graphene |
5.15. | Advanced carbon structures made from CO2: Technology |
5.16. | Producing graphene as an electronic substrate or material |
5.17. | Chemical Vapour Deposited (CVD) Graphene |
5.18. | Growth process of CVD graphene |
5.19. | The key role of oxygen in CVD graphene growth |
5.20. | CVD graphene: cm scale grain domains possible |
5.21. | Roll to roll (R2R) growth of CVD graphene film |
5.22. | The transfer challenge: a showstopper? |
5.23. | Roll-to-roll transfer of CVD graphene |
5.24. | Novel methods for transferring CVD graphene |
5.25. | Using R2R joule heating to enable CVD growth |
5.26. | Epitaxial: high performance but high cost |
5.27. | Graphene from SiC |
5.28. | Metal on silicon CVD (then transfer) |
5.29. | Transfer-FREE metal on Si graphene |
5.30. | Single crystal wafer scale graphene on silicon |
5.31. | CVD Graphene Progress |
6. | ENERGY STORAGE: BATTERIES |
6.1. | Energy storage: Graphene overview |
6.2. | Graphene batteries introduction |
6.3. | Graphene-enabled energy storage devices: Overview |
6.4. | Lithium-ion battery market outlook |
6.5. | Types of lithium battery |
6.6. | Battery technology comparison |
6.7. | Timeline and outlook for Li-ion energy densities |
6.8. | Main Graphene Players - Energy Storage |
6.9. | LFP cathode improvement |
6.10. | Why graphene and carbon black are used together |
6.11. | Results showing graphene improves LFP batteries |
6.12. | Results showing graphene improves NCM batteries |
6.13. | Results showing graphene improves LTO batteries |
6.14. | Why silicon anode battery and key challenges? |
6.15. | Silicon anodes |
6.16. | Electrolyte and current collectors |
6.17. | Fast charging lithium-ion batteries |
6.18. | Motivation - why Lithium sulphur batteries? |
6.19. | The Lithium sulphur battery chemistry |
6.20. | Why graphene helps in Li sulphur batteries |
6.21. | State of the art use of graphene in LiS batteries |
6.22. | Mixed graphene/CNT in batteries |
6.23. | Graphene-enabled lead acid battery |
6.24. | Aluminum-ion batteries |
6.25. | Graphene battery announcements |
6.26. | Conclusions: graphene role in batteries |
7. | ENERGY STORAGE: SUPERCAPACITORS |
7.1. | Energy Storage Priorities |
7.2. | Supercapacitor fundamentals |
7.3. | Batteries vs supercapacitors |
7.4. | Competition from other carbon nanostructures |
7.5. | Challenges with graphene: poor out-of-plane conductivity and re-stacking |
7.6. | Graphene supercapacitors players |
7.7. | Graphene supercapacitor Ragone plots |
7.8. | Promising results on GO supercapacitors |
7.9. | Key Player: Skeleton Technologies |
7.10. | Targeted high-volume production |
7.11. | Graphene supercapacitor products and outlook - new product launches over the full range |
7.12. | Graphene supercapacitor products and outlook - wide range of applications |
7.13. | Future iterations - graphene hydrogels and aerogels? |
7.14. | Conclusions: graphene role in supercapacitors |
8. | THERMAL MANAGEMENT |
8.1. | Thermal Management |
8.2. | Thermal management applications |
8.3. | Introduction to Thermal Interface Materials (TIM) |
8.4. | Advanced Materials for TIM - Introduction |
8.5. | Summary of TIM utilising advanced carbon materials |
8.6. | Achieving through-plane alignment |
8.7. | Graphene heat spreaders: commercial success |
8.8. | Graphene heat spreaders: performance |
8.9. | Graphene heat spreaders: suppliers multiply |
8.10. | Graphene as a thermal paste additive |
8.11. | Graphene as additives to thermal interface pads |
8.12. | Graphene: heat conductivity boosters |
8.13. | Nanofluidic coolant |
9. | POLYMER ADDITIVE |
9.1.1. | General observation on using graphene additives in composites |
9.2. | Mechanical |
9.2.1. | Evidence for mechanical property improvement |
9.2.2. | Results showing Young's Modulus enhancement using graphene |
9.2.3. | Commercial results on permeation graphene improvement |
9.2.4. | Permeation Improvement |
9.2.5. | Graphene providing enhanced fire retardancy |
9.3. | Conductive |
9.3.1. | Graphene platelet-based conductors: polymer composites |
9.3.2. | Thermal conductivity improvement using graphene |
9.3.3. | Electrical conductivity improvement using graphene |
9.3.4. | EMI Shielding: graphene additives |
9.3.5. | Commercial studies |
9.4. | Commercial applications |
9.4.1. | Key adoption examples - sports & leisure |
9.4.2. | Key adoption examples - automotive |
9.4.3. | Key adoption examples - industrial |
9.4.4. | Mechanical Polymer: Adoption Examples - Packaging |
9.4.5. | Mechanical Polymer: Adoption Examples - Elastomers |
9.4.6. | Graphene-enhanced conductive 3D printing filaments |
9.4.7. | Intermediate players |
10. | FIBER REINFORCED POLYMER (FRP) ADDITIVE |
10.1. | Role of nanocarbon as additives to FRPs |
10.2. | Routes to incorporating nanocarbon material into composites |
10.3. | Routes to electrically conductive composites |
10.4. | Technology adoption for electrostatic discharge of composites |
10.5. | Nanocarbon for enhanced electrical conductivity - Graphene |
10.6. | Enhanced thermal conductivity - application overview |
10.7. | Electrothermal de-icing - Nanocarbon patents |
10.8. | Electrothermal de-icing - Graphene research |
10.9. | Nanocomposites for enhanced thermal conductivity - graphene |
10.10. | Embedded sensors for structural health monitoring of composites - introduction |
10.11. | Embedded sensors for structural health monitoring of composites - types |
10.12. | Nanocarbon Sensors for embedded SHM |
11. | GRAPHENE CONDUCTIVE INKS |
11.1. | Graphene platelet/powder-based conductors: conductive inks |
11.2. | Applications of conductive graphene inks |
11.3. | Results of resistive heating using graphene inks |
11.4. | Heating applications |
11.5. | Uniform and stable heating |
11.6. | Results of de-frosting using graphene inks |
11.7. | Results of de-icing using graphene heaters |
11.8. | Transparent EMI shielding |
11.9. | ESD films printed using graphene |
11.10. | Graphene inks can be highly opaque |
11.11. | RFID types and characteristics |
11.12. | Graphene RFID tags |
12. | SENSORS |
12.1. | Industry examples of graphene-based sensors |
12.2. | Graphene Sensors - Gas Sensors |
12.3. | Gas sensors - Overview |
12.4. | Graphene sensor for food safety monitoring |
12.5. | Biosensor - electrochemical transducer overview |
12.6. | Graphene-based BioFET |
12.7. | Graphene Sensors - Biosensors |
12.8. | Graphene Sensors - COVID-19 |
12.9. | Graphene Quantum Dots |
12.10. | Hall-effect sensor |
12.11. | Graphene's optical properties |
12.12. | Fast graphene photosensor |
12.13. | Commercial example of graphene-enabled photodetector |
12.14. | Emberion: QD-Graphene-Si broadrange SWIR sensor |
12.15. | Emerging role in silicon photonics |
12.16. | New graphene photonic companies |
12.17. | Academic research: Twisted bilayer graphene sensitive to longer wavelength IR light |
12.18. | QD-on-CMOS with graphene interlayer |
12.19. | Graphene humidity sensor |
12.20. | Optical brain sensors using graphene |
12.21. | Graphene skin electrodes |
12.22. | Graphene-enabled stretch sensor applications |
13. | TRANSPARENT CONDUCTIVE FILMS AND GLASS |
13.1. | Transparent conducting films (TCFs) |
13.2. | Different Transparent Conductive Films (TCFs) |
13.3. | ITO film shortcomings: flexibility |
13.4. | ITO film shortcomings: limited sheet conductivity |
13.5. | Indium's single supply risk: real or exaggerated? |
13.6. | Graphene performance as TCF |
13.7. | Doping as a strategy for improving graphene TCF performance |
13.8. | Be wary of extraordinary results for graphene |
13.9. | Graphene transparent conducting films: thinness and barrier layers |
13.10. | LG Electronics: R2R CVD graphene targeting TCFs? |
13.11. | Hybrid materials (I) : Properties |
13.12. | Hybrid materials (II): Chasm |
14. | GRAPHENE TRANSISTORS |
14.1. | Introduction to transistors |
14.2. | Transistor Figures-of-Merit (transfer characteristics) |
14.3. | Transistor Figures-of-Merit (output characteristics) |
14.4. | Why graphene transistors? |
14.5. | First graphene FET with top gate (CMOS)- 2007 |
14.6. | High performance top gate FET |
14.7. | Graphene FET with bandgap |
14.8. | Opening a bandgap: e-field induced bandgap bilayer graphene |
14.9. | Opening bandgap: No free lunch! |
14.10. | Graphene wafer scale integration |
14.11. | Can graphene FETs make it as an analogue high frequency device? |
14.12. | So what if we print graphene? Poor competition gives hope! |
14.13. | Fully inkjet printed 2D material FETs |
14.14. | Fully inkjet printed 2D material FETs on TEXTILE |
14.15. | Fully inkjet printed on-textile 2D material logic! |
14.16. | Graphene transistor conclusions |
15. | MEMBRANES |
15.1. | Introduction to membranes |
15.2. | Stacked Graphene Oxide |
15.3. | Applications in paper/pulp industry |
15.4. | Lockheed Martin graphene membrane |
15.5. | Printed GO membranes |
15.6. | Lithium extraction |
15.7. | Emulsion separation |
15.8. | Membrane players |
15.9. | Filtration - Commercial launches |
15.10. | Latest research for water filtration |
15.11. | Sensors |
15.12. | Electronics |
15.13. | Fuel cells |
16. | OTHER APPLICATIONS |
16.1. | Concrete & asphalt: Overview |
16.2. | Concrete & asphalt: Research and demonstrations |
16.3. | Concrete & asphalt: Graphene outlook |
16.4. | Graphene textiles |
16.5. | Graphene textile uptake |
16.6. | Headphones |
16.7. | Lubricants |
16.8. | Engine oil |
16.9. | Copper nanocomposites - introduction |
16.10. | Production of copper nanocomposites |
16.11. | Graphene platelet-based conductors: metal composites |
16.12. | Metal composite developments |
16.13. | Metal additive manufacturing |
16.14. | Hot extrusion nanoalloy |
16.15. | Multilayer copper nanocomposites |
16.16. | Ceramic composite developments |
16.17. | Graphene as additive in tires |
16.18. | Results on use of graphene in silica loaded tires |
16.19. | Graphene-enabled vehicle tire |
16.20. | Graphene-enabled bike tires |
16.21. | Anti-corrosion coating |
16.22. | Other coatings |
16.23. | Graphene UV shielding coatings |
16.24. | Antimicrobial: graphene research |
16.25. | Antimicrobial: graphene applications |
17. | ANALYSIS OF GNP, GO, RGO MANUFACTURERS |
17.1. | Comprehensive list and analysis of graphene manufacturers |
18. | 2D MATERIALS BEYOND GRAPHENE |
18.1.1. | 2D materials beyond graphene: A GROWING family! |
18.1.2. | Computation suggests thousands available |
18.1.3. | "Atomic lego" - the future of material science? |
18.1.4. | 2D materials beyond graphene: a GROWING family! |
18.1.5. | Publication rate is astronomical |
18.1.6. | A range of 2D materials exist with bandgaps! |
18.2. | Nano Boron Nitride |
18.2.1. | Introduction to Nano Boron Nitride |
18.2.2. | BNNT players and prices |
18.2.3. | BNNT property variation |
18.2.4. | BN nanostructures in thermal interface materials |
18.2.5. | BNNT developments |
18.2.6. | BN vs C nanostructures: Manufacturing routes |
18.2.7. | BNNS - manufacturing status |
18.2.8. | BNNS - research advancements |
18.3. | Transition Metal Dichalcogenides |
18.3.1. | TMD overview |
18.3.2. | TMD - Novel manufacturing method for MoS2 |
18.3.3. | MoS2: Change in band structure from bulk to 2D |
18.3.4. | 2D materials working: top gate FET |
18.3.5. | Wafer scale uniform TMD growth |
18.3.6. | Latest research to 300mm wafers |
18.3.7. | TMDs: Major players |
18.4. | MXenes |
18.4.1. | MXenes: A rapidly emerging class |
18.4.2. | MXenes - Application opportunities |
18.4.3. | MXenes - Latest research |
18.4.4. | MXenes - Latest Research (2) |
18.5. | Phosphorene |
18.5.1. | Phosphorene |
18.5.2. | Phosphorene - Manufacturing |
18.5.3. | Phosphorene - Manufacturing (2) |
18.5.4. | Phosphorene - Biomedical applications |
18.6. | Other 2D Materials |
18.6.1. | Other 2D materials |
18.6.2. | 2.5D Materials |
18.6.3. | Materials SWOT comparison |
Slides | 400 |
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Forecasts to | 2033 |
ISBN | 9781915514080 |