Cambridge Modelling is working with a leading supercapacitor manufacturer on a new type of commercial supercapacitor based on a high capacitance nanocomposite material that offers superior energy density alongside high power performance. The nanocomposite material was originally developed at the University of Cambridge and has since been refined and optimised by Cambridge Modelling, which holds the intellectual property and know-how relating to the synthesis and application of this novel nanocomposite material.
Cambridge Modelling’s work with the University of Cambridge on new battery technologies for hybrid and electric vehicles has been expanded to include cell operation and thermal management modelling.
Cambridge Modelling is working in collaboration with the University of Cambridge and Cambridge Nanomaterials Technology to develop a new energy storage technology targeted for use in electric and hybrid vehicles. Cambridge Modelling is providing Monte Carlo modelling to help optimise the materials design and experimental program in this project.
Supercapacitors are devices used to store and deliver electrical energy in high power pulses. With the advent of electric vehicles, digital communication and other electronic devices that require significant bursts of electrical energy, the need for supercapacitors has expanded rapidly. At present, the most promising materials on which supercapacitors are based can be divided into two categories – those that make use of a double-layer charge storage mechanism (e.g. carbon nanotubes, carbon aerogels and activated carbon black) and those employing a redox pseudo-capacitive charge storage mechanism (e.g. conducting polymers and transition metal oxides). Already, the electrical charge that can be stored in each of these materials is typically several orders of magnitude larger than that of most commercially available conventional capacitors. However, it has been shown in recent times that even greater charge storage capacitances can be achieved in composites made by combining carbon nanotubes (a double-layer capacitive material) with a conducting polymer (a redox pseudo-capacitive material). The superior charge storage performance of carbon nanotube-conducting polymer composite supercapacitors arises from their ability to merge the properties that separately make carbon nanotubes and conducting polymers so suited to their respective charge storage mechanisms. That is to say, the composites are able to combine the high surface area and electrical conductivity of carbon nanotubes with the redox electrochemistry of conducting polymers.