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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. | Graphene-enabled products and important prototypes |
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 enhancement |
10.9. | 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. | AzTrong |
16.8. | Bayer MaterialScience AG (now left the business) |
16.9. | Bluestone Global Tech |
16.10. | C3Nano |
16.11. | Cabot Corporation |
16.12. | Cambridge Nanosystems |
16.13. | Canatu |
16.14. | Charmtron Inc |
16.15. | CNano Technology |
16.16. | CrayoNano |
16.17. | Directa Plus |
16.18. | g2o |
16.19. | Gnanomat |
16.20. | Grafen Chemical Industries |
16.21. | Grafentek |
16.22. | Grafoid |
16.23. | Graphenano |
16.24. | Graphene 3D Lab |
16.25. | Graphene Frontiers |
16.26. | Graphene Laboratories, Inc |
16.27. | Graphene Square |
16.28. | Graphene Technologies |
16.29. | Graphenea |
16.30. | Group NanoXplore Inc. |
16.31. | Grupo Antolin Ingenieria |
16.32. | Incubation Alliance |
16.33. | Jinan Moxi New Material Technology |
16.34. | Nanjing JCNANO Technology |
16.35. | Nanocyl |
16.36. | NanoInnova |
16.37. | NanoIntegris |
16.38. | Nantero |
16.39. | Nanomedical Diagnostics |
16.40. | OCSiAl |
16.41. | OneD Material LLC |
16.42. | Perpetuus Graphene |
16.43. | Poly-Ink |
16.44. | Pyrograf Products |
16.45. | Raymor Industries, Inc. |
16.46. | Showa Denko K.K |
16.47. | SiNode Systems |
16.48. | Skeleton Technologies |
16.49. | SouthWest NanoTechnologies, Inc. |
16.50. | The Sixth Element |
16.51. | Thomas Swan |
16.52. | Timesnano |
16.53. | Unidym Inc |
16.54. | Vorbeck Materials |
16.55. | Wuxi Graphene Film |
16.56. | XFNANO |
16.57. | XG Sciences, Inc. |
16.58. | Xiamen Knano |
16.59. | XinNano Materials Inc |
16.60. | Xolve, Inc |
16.61. | 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 |
IDTECHEX RESEARCH REPORTS AND CONSULTANCY |
슬라이드 | 235 |
---|---|
Companies | 112 |
전망 | 2026 |