During the first 18 months of the project EMPHASIS, significant progress has been made in respect to the main objectives and the Key Performance Indicators that were envisaged at the start of the project. In general, the main material research that was focused on the delivery of innovative and more sustainable supercapacitor components has already delivered materials and technology with significantly improved performance. As aforementioned, EMPHASIS has a holistic approach on the development of new material technologies in every aspect of a supercapacitor.
The next 18 months the project will focus on the integration of these material technologies to supercapacitor cells and the manufacturing of the demonstrators for the two applications that the project has specified (electromobility & smart clothing). In more specific, EMPHASIS project during the first 18 months has achieved the following:
-Fabrication of flexible laser-processed graphene-based supercapacitor electrodes with increased areal capacitance (Areal capacitance: 18 mF/cm2)
-Development of optimized activated carbon & activated carbon fibers based sustainable precursor fibers (Specific Capacitance: 180 F/g, Surface area: 2429 m2/g, Pore size: 0.5 – 10 nm)
-Development of light weight carbon-based current collectors with increased electrical conductivity (Electrical conductivity: 105 S/m, Areal density: 20-25 g/m2)
-Development of ionic liquid-based electrolytes with increased ionic conductivity and wider potential window and operating temperature window (Ionic conductivity >20 mS/cm, Cut-off voltage up to 3.6V achieved, Temperature window: -50 oC to 100 oC, Energy Density measured: >20 Wh/kg in lab conditions)
-In silico prediction of the electrochemical stability window of electrolyte mixtures and room-temperature ionic liquids and development and testing of classical molecular dynamics methodologies for the study of electrolyte mixtures in conjunction with graphitic electrodes
-Definition of the application that include the supercapacitor requirements for both applications (SC cells of 200 F for electromobility applications and flexible SC cells for smart clothing)
-Development of the new measuring methods more suitable for supercapacitor cells