Table of Contents 1. INTRODUCTION 1.1. There are many graphene types 1.2. Many ways of producing graphene 1.3. Explaining the main graphene manufacturing routes 1.4. Morphologies of graphene on offer 1.5. Market conditions, trends and outlook 1.6. General observations on the market situation 1.7. Moving past the peak of hype 1.8. Supplier numbers on the rise 1.9. Media attention and patent publications on the rise 1.10. Large scale investment in graphene research 1.11. Investment in graphene company formation 1.12. Revenue of graphene companies 1.13.The industry is still in the red 1.14. Initial public offerings 1.15. Information on supplier morphology, investment & revenue 1.16. The rise of China 1.17. China was successful in carbon nanotubes 1.18. Patent trends 1.19. Graphite mines see opportunity in graphene 1.20. Production capacity by player 1.21. The importance of intermediaries 1.22. Graphene Prices and Pricing Strategy 1.23. Quality and consistency issue 1.24. Graphene application pipeline 1.25. Current graphene-enabled products 1.26. Benchmarking graphene suppliers 2. MARKET PROJECTIONS 2.1. Granular ten year graphene market forecast 2.2. Ten year graphene market forecast 2.3. Forecast for graphene platelet vs sheets 2.4. Graphene market in 2019 2.5. Graphene market in 2026 2.6. Forecast for volume (MT) demand for graphene platelets 3. GRAPHENE PRODUCTION 3.1. Expanded graphite 3.2. Reduced graphene oxide 3.3. Oxidising graphite 3.4. Reducing graphene oxide 3.5. Direct liquid phase exfoliation 3.6. Direct liquid phase exfoliation under shear force 3.7. Electrochemical exfoliation 3.8. Properties of electrochemical exfoliated graphene 3.9. Plasma exfoliation 3.10. Substrate-less CVD 3.11. Substrate-less CVD (plasma) 3.12. Chemical vapour deposition (CVD) 3.13. Chemical vapour deposition 3.14. Transfer process for chemical vapour deposition 3.15. Roll-to-roll transfer of CVD graphene 3.16. Novel methods for transferring CVD graphene 3.17. Sony's approach to transfer of CVD process 3.18. Sony's CVD graphene approach 3.19. Wuxi Graphene Film Co's CVD graphene progress 3.20. Direct growth of CVD on SiOx? 3.21 Production cost of CVD graphene 3.22. Epitaxial 3.23. Largest single-crystalline graphene reported ever
4. GRAPHENE MATERIALS 4.1. Pictures of graphene materials
5. GRAPHENE APPLICATIONS AND MARKETS
6. TRANSPARENT CONDUCTIVE FILMS 6.1. Indium Tin Oxide 6.2. Market forecast for transparent conducting films 6.3. Performance of ITO films on the market 6.4. Production cost and flexibility of ITO films 6.5. Supply and demand for ITO films and indium 6.6. Changing TCF market dynamics and needs 6.7. Assessment of ITO alternatives 6.8. Graphene performance as TCF 6.9. SWOT analysis on graphene TCFs 6.10. Performance of silver nanowire TCFs 6.11. Flexibility of silver nanowire TCFs 6.12. Silver nanowire TCF cost structure 6.13. Silver nanowire products on the market 6.14. Metal mesh TCF performance 6.15. Flexibility of metal mesh TCFs 6.16. Performance of carbon nanotube TCFs 6.17. Useful information on carbon nanotube TCFs 6.18. Benchmarking TCF technologies 6.19. Make or break year for ITO alternatives? 6.20. Consolidation period for the ITO alternative market 6.21. ITO alternative ten-year market forecast
7. GRAPHENE CONDUCTIVE INKS 7.1. Performance of Graphene conductive inks 7.2. Applications of conductive graphene inks 7.3. Resistive heating using graphene inks 7.4. De-frosting using graphene inks 7.5.De-icing using graphene heaters 7.6.Transparent EMI shielding 7.7.Graphene-enabled products and important prototypes 7.8. Graphene inks can be highly opaque 7.9. RFID types 7.10. RFID antenna market figures 7.11. RFID antennas 7.12. Cost breakdown of RFID tags 7.13. Methods of producing RFID antennas
8. SUPERCAPACITORS 8.1. Ten-year market forecast for supercapacitors by application 8.2. Application pipeline for supercapacitors 8.3. Cost structure of a supercapacitor 8.4. Cost breakdown of supercapacitors 8.5. Supercapacitor electrode mass in transport applications 8.6. Addressable market forecast for supercapacitor electrodes 8.7. Supercapacitor performance using nanocarbons 8.8. Performance of existing commercial supercapacitors 8.9. Challenges with graphene 8.10. Graphene surface area is far from the ideal case 8.11. Promising results on graphene supercapacitors 8.12. Performance of carbon nanotube supercapacitors 8.13. Potential benefits of carbon nanotubes 8.14. Challenges with the use of carbon nanotubes 8.15. Electrode chemistries of supercapacitor suppliers
9. ENERGY STORAGE 9.1. Historical progress in Li ion batteries 9.2. Quantitative benchmarking of Li and post-Li ion batteries 9.3. Quantitative benchmarking of Li and post-Li ion batteries 9.4. EV numbers used in this projections 9.5. Electrode mass by battery type 9.6. Cost breakdown of Li ion batteries 9.7. LFP cathode improvement 9.8. Why graphene and carbon black are used together 9.9. Graphene improves NCM battery cathode 9.10. LiTiOx anode Improvement 9.11. How CNT improve the performance of commercial Li ion batteries 9.12. Why graphene helps in Si anode batteries 9.13. State of the art in silicon-graphene anode batteries 9.14. Samsung's result on Si-graphene batteries 9.15.State of the art in silicon-graphene anode batteries 9.16.Why graphene helps in Li sulphur batteries 9.17.State of the art in use of graphene in Li Sulphur batteries 9.18.Graphene battery announcement 9.19.Graphene-enabled products and important prototypes
10. COMPOSITES 10.1.General observation on using graphene additives in composites 10.2.Commercial results on graphene conductive composites 10.3.Conductive composites 10.4.EMI Shielding 10.5.How do CNTs do in conductive composites 10.6.CNT success in conductive composites 10.7.Examples of products that use CNTs in conductive plastics 10.8.Young's Modulus enhancement10.9.Commercial results on permeation graphene improvement 10.10.Permeation Improvement 10.11.Thermal conductivity improvement 10.12.Commercial results on thermal conductivity improvement using graphene 10.13.Thermal conductivity improvement using graphene
11. GRAPHENE AND 2D MATERIALS FOR TRANSISTORS 11.1. Performance of graphene transistors 11.2. Graphene transistor based on work function modulation 11.3. Other 2D materials are better at creating transistor functions 11.4. Mobility of 2D materials as a function of bandgap 11.5. Suitability of 2D materials for large-area flexible devices 11.6. Effect of growth method on mobility
12. TIRES 12.1. Graphene as additive in tires 12.2. Progress on graphene-enabled bicycle tires 12.3. Carbon black in tires 12.4. Black carbon in car tires 12.5. There are many types of black carbon 12.6. CNT and graphene are the least ready emerging tech for tire improvement 12.7. Results on use of graphene in silica loaded tires 12.8. Comments on CNT and graphene in tires 12.9. Total addressable market for graphene in tires
13. SENSORS 13.1. Graphene GFET sensors 13.2. Fast graphene photosensor 13.3. Graphene humidity sensor 13.4. Optical brain sensors using graphene 13.5. Graphene skin electrodes 13.6. Wearable stretch sensor using graphene
14. OTHER APPLICATIONS 14.1. Anti-corrosion coating 14.2. Water filtration 14.3. Lockheed Martin's water filtration 14.4. Graphene-enhanced condoms? 14.5. Future applications
15. REVIEW OF PROGRESS WITH CARBON NANOTUBES 15.1. Carbon nanotubes- the big picture 15.2. Carbon nanotubes are more mature than graphene 15.3. Carbon nanotubes prices are falling 15.4. Already commercial applications of CNTs 15.5. Application Timeline 15.6. Production capacity of carbon nanotubes 15.7. Loss of differentiation in CNTs 15.8. Differentiating between CNTs and graphene 15.9. Will the CNT industry consolidate? 15.10. Player dynamics in the CNT business 15.11. Ten-year market forecast for MWCNTs
16. INTERVIEW BASED COMPANY PROFILES 16.1.Abalonyx AS 16.2.Advanced Graphene Products 16.3.Anderlab Technologies Pvt. Ltd. 16.4.Angstron Materials 16.5.Applied Graphene Materials 16.6.Arkema 16.7.Bayer MaterialScience AG (now left the business) 16.8.Bluestone Global Tech (now left the business) 16.9.C3Nano 16.10.Cabot Corporation 16.11.Cambridge Nanosystems 16.12.Canatu 16.13.Charmtron Inc 16.14.CNano Technology 16.15.CrayoNano16.16.Directa Plus 16.17.g2o 16.18.Gnanomat 16.19.Grafen Chemical Industries 16.20.Grafentek 16.21.Grafoid 16.22.Graphenano 16.23.Graphene 3D Lab 16.24.Graphene Frontiers 16.25.Graphene Laboratories, Inc 16.26.Graphene Square 16.27.Graphene Technologies 16.28.Graphenea 16.29.Group NanoXplore Inc. 16.30.Grupo Antolin Ingenieria 16.31.Incubation Alliance 16.32.Jinan Moxi New Material Technology 16.33.Nanjing JCNANO Technology 16.34.Nanocyl 16.35.NanoInnova 16.36.NanoIntegris 16.37.Nantero 16.38.OCSiAl 16.39.OneD Material LLC 16.40.Perpetuus Graphene 16.41.Poly-Ink 16.42.Pyrograf Products 16.43.Raymor Industries, Inc. 16.44.Showa Denko K.K 16.45.SiNode Systems 16.46.Skeleton Technologies 16.47.SouthWest NanoTechnologies, Inc. 16.48.The Sixth Element 16.49.Thomas Swan 16.50.Timesnano 16.51.Unidym Inc 16.52.Vorbeck Materials 16.53.Wuxi Graphene Film 16.54.XFNANO 16.55.XG Sciences, Inc. 16.56.Xiamen Knano 16.57.XinNano Materials Inc 16.58.Xolve, Inc 16.59.Zyvex
17. COMPANY PROFILES 17.1. 2D Carbon Graphene Material Co., Ltd 17.2. Airbus, France 17.3. Aixtron, Germany 17.4. AMO GmbH, Germany 17.5. Asbury Carbon, USA 17.6. AZ Electronics, Luxembourg 17.7. BASF, Germany 17.8. Cambridge Graphene Centre, UK 17.9. Cambridge Graphene Platform, UK 17.10. Carben Semicon Ltd, Russia 17.11. Carbon Solutions, Inc., USA 17.12. Catalyx Nanotech Inc. (CNI), USA 17.13. CRANN, Ireland 17.14. Georgia Tech Research Institute (GTRI), USA 17.15. Grafoid, Canada 17.16. Graphene Devices, USA 17.17. Graphene NanoChem, UK 17.18. Graphensic AB, Sweden 17.19. HDPlas, USA 17.20. Head, Austria 17.21. HRL Laboratories, USA 17.22. IBM, USA 17.23. iTrix, Japan 17.24. JiangSu GeRui Graphene Venture Capital Co., Ltd. 17.25. Lockheed Martin, USA 17.26. Massachusetts Institute of Technology (MIT), USA 17.27. Max Planck Institute for Solid State Research, Germany 17.28. Momentive, USA 17.29. Nanjing JCNANO Tech Co., LTD 17.30. Nanjing XFNANO Materials Tech Co.,Ltd 17.31. Nanostructured & Amorphous Materials, Inc., USA 17.32. Nokia, Finland 17.33. Pennsylvania State University, USA 17.34. Power Booster, China 17.35. Quantum Materials Corp, India 17.36. Rensselaer Polytechnic Institute (RPI), USA 17.37. Rice University, USA 17.38. Rutgers - The State University of New Jersey, USA 17.39. Samsung Electronics, Korea 17.40. Samsung Techwin, Korea 17.41. SolanPV, USA 17.42. Spirit Aerosystems, USA 17.43. Sungkyunkwan University Advanced Institute of Nano Technology (SAINT), Korea 17.44. Texas Instruments, USA 17.45. Thales, France 17.46. University of California Los Angeles, (UCLA), USA 17.47. University of Manchester, UK 17.48. University of Princeton, USA 17.49. University of Southern California (USC), USA 17.50. University of Texas at Austin, USA 17.51. University of Wisconsin-Madison, USA
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