PRN: Supercapacitor Materials 2017-2027: A Multibillion Dollar Market for the Materials is in Prospect but Not Overnight

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Supercapacitor Materials 2017-2027: A Multibillion Dollar Market for the Materials is in Prospect but Not Overnight


DUBLIN, September 4, 2017 /PRNewswire/ --

The "Supercapacitor Materials 2017-2027" report has been added to Research and Markets' offering.

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"Supercapacitor Materials 2017-2027", explains how, out of the spotlight, very important advances are occurring even beyond market leader Maxwell's superlative opening up of new applications with tailored products. In the desert for supercapacitor manufacture - Europe - Skeleton Technologies has started to make supercapacitors partially based on graphene that set the record for power density and Yunasko in the Ukraine set the record for production hybrid supercapacitor energy density - up near lead acid and NiCd batteries and something Nippon Chemical says it will match next year.

The report has a global sweep. From ongoing visits, it explains how, recognising the distaste of the Japanese motor industry for highly toxic electrolytes, Nippon Chemical in Japan jumped from nowhere to number two in supercapacitors in the world by making supercapacitors for cars that had benign electrolytes. "Supercapacitor Materials 2017-2027" expresses the view that, partly because its supercapacitor suppliers have become more capable, China has recently reversed its policy on traditional hybrid vehicles, declaring that in 2030, 30% of cars made would be hybrids that do not plug in - candidates for supercapacitors. With GM now adopting them, supercapacitors are rapidly taking market share of stop-start systems for conventional vehicles.

"Supercapacitor Materials 2017-2027" finds that electrolytes with totally new chemistry are pairing well with new exohedral active electrodes. Hybrid capacitors are benefitting from totally new electrolyte-electrode pairings in the laboratory at least. Are the old rules of extremely hydrophobic assembly following complex high temperature processes really necessary for best performance? Everything is being questioned now.

Learn how, in 2016-7, researchers at MIT and elsewhere developed a supercapacitor using no conductive carbon that will potentially store much more power. Learn how the British have entered the fray, announcing new large molecule electrolytes based on large organic molecules composed of many repeated sub-units and bonded together to form a 3-dimensional network. Appraise the opportunity to match lithium-ion battery energy density without the short cycle life, poor power density and safety issues of a battery. Are we going to have "batteries" that can be fully discharged for safe transit and safe retrieval in a car crash unlike real Li-ion batteries?

Learn how, in three countries, researchers are making supercapacitors that are load-bearing structures and others demonstrate stretchable supercapacitor fibers being woven, things batteries cannot do even when solid state because they swell and shrink on cycling. Other old certainties are being questioned as well, each advance potentially opening up large new applications. A multibillion dollar market for the materials is in prospect but not overnight. Now is the time to investigate and invest and the report, "Supercapacitor Materials 2017-2027" goes right to the added value emerging.

Key Topics Covered:

1.1. Comparison with batteries
1.2. Comparison with electrolytic capacitors
1.3. Focus on functional materials
1.4. Options: operating principles
1.5. What needs improving?
1.6. Construction and cost structure
1.7. Choices of material: important parameters to improve
1.8. Progress with electrode materials
1.9. Electrolytes
1.10. Supercabatteries
1.11. Graphene goes well with the new electrolytes
1.12. Materials maturity and profit
1.13. Market forecast 2017-2027
1.14. Hemp pseudo graphene?
1.15. Supercapacitors on the smaller scale
1.16. Supercapacitor materials news

2.1. Where supercapacitors fit in
2.2. Supercapacitors and supercabattery basics
2.3. Supercapacitors and alternatives compared
2.4. Fundamentals
2.5. Laminar biodegradable option
2.6. Structural supercapacitors
2.7. Electrolyte improvements ahead
2.8. Equivalent circuits and limitations
2.9. Supercapacitor sales have a new driver: safety
2.10. Disruptive supercapacitors now taken more seriously
2.11. Change of leadership of the global value market?
2.12. Battery and fuel cell management with supercapacitors
2.13. Graphene vs other carbon forms in supercapacitors
2.14. Environmentally friendlier and safer materials
2.15. Printing supercapacitors
2.16. New manufacturing sites in Europe
2.17. Modelling insights


4.1. Introduction
4.2. Toxicity
4.3. Gel electrolytes!
4.4. Ionic liquids
4.5. Electrolytes compared by manufacturer.

5.1. Introduction
5.2. Electrodes and other materials compared by company
5.3. Materials optimisation
5.4. Progress with electrode materials
5.5. Graphene
5.6. Higher voltage electrolytes
5.7. Aqueous electrolytes become attractive
5.8. Organic ionic electrolytes
5.9. Acetonitrile concern
5.10. Supercabattery improvement

6.1. 2D Carbon Graphene Material Co., Ltd
6.2. Abalonyx, Norway
6.3. Airbus, France
6.4. Aixtron, Germany
6.5. AMO GmbH, Germany
6.6. Asbury Carbon, USA
6.7. AZ Electronics, Luxembourg
6.8. BASF, Germany
6.9. Cambridge Graphene Cen! tre, UK< br/>6.10. Cambridge Graphene Platform, UK
6.11. Carben Semicon Ltd, Russia
6.12. Carbon Solutions, Inc., USA
6.13. Catalyx Nanotech Inc. (CNI), USA
6.14. CRANN, Ireland
6.15. Georgia Tech Research Institute (GTRI), USA
6.16. Grafoid, Canada
6.17. GRAnPH Nanotech, Spain
6.18. Graphene Devices, USA
6.19. Graphene NanoChem, UK
6.20. Graphensic AB, Sweden
6.21. Harbin Mulan Foreign Economic and Trade Company, China
6.22. HDPlas, USA
6.23. Head, Austria
6.24. HRL Laboratories, USA
6.25. IBM, USA
6.26. iTrix, Japan
6.27. JiangSu GeRui Graphene Venture Capital Co., Ltd.
6.28. Jinan Moxi New Material Technology Co., Ltd
6.29. JSR Micro, Inc. / JM Energy Corp.
6.30. Lockheed Martin, USA
6.31. Massachusetts Institute of Technology (MIT), USA
6.32. Max Planck Institute for Solid State Research, Germany
6.33. Momentive, USA
6.34. Nanjing JCNANO Tech Co., LTD
6.35. Nanjing XFNANO Materials Tech Co.,Ltd
6.36. Nanostructured & Amorphous Materials, Inc., USA
6.36.1. Nippon ChemiCon/ United ChemiCon Japan
6.37. Nokia, Finland
6.38. Pennsylvania State University, USA
6.39. Power Booster, China
6.40. Quantum Materials Corp, India
6.41. Rensselaer Polytechnic Institute (RPI), USA
6.42. Rice University, USA
6.43. Rutgers - The State University of New Jersey, USA
6.44. Samsung Electronics, Korea
6.45. Samsung Techwin, Korea
6.46. SolanPV, USA
6.47. Spirit Aerosystems, USA
6.48. Sungkyunkwan University Advanced Institute of Nano Technology (SAINT), Korea
6.48.1. Taiyo Yuden
6.49. Texas Instruments, USA
6.50. Thales, France
6.51. The Sixth Element
6.52. University of California Los Angeles, (UCLA), USA
6.53. University of Manchester, UK
6.54. University of Princeton, USA
6.55. University of Southern California (USC), USA
6.56. University of Surrey UK
6.57. University of Texas at Austin, USA
6.58. University of Wisconsin-Madison, USA

For more information about this report visit

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