Monash develops compact supercapacitors with energy storage similar to conventional batteries
Next-generation energy storage is now a step closer with Monash University researchers developing an engineering first - a graphene-based device that is compact, yet lasts as long as a conventional battery.
Published in Science, a research team led by Professor Dan Li of the Department of Materials Engineering has developed a completely new strategy to engineer graphene-based supercapacitors (SC), making them viable for widespread use in renewable energy storage, portable electronics and electric vehicles.
SCs are generally made of highly porous carbon impregnated with a liquid electrolyte to transport the electrical charge. Known for their almost indefinite life span and the ability to recharge in seconds, the drawback of existing SCs is their low energy-storage-to-volume ratio - known as energy density. Low energy density of 5-8 Wh/L means SCs are unfeasibly large or must be recharged frequently.
Professor Li’s team has created an SC with energy density of 60 Wh/L - comparable to lead-acid batteries and around 12 times higher than commercially available SCs.
“It has long been a challenge to make SCs smaller, lighter and compact to meet the increasingly demanding needs of many commercial uses,” Professor Li said.
Graphene, which is formed when graphite is broken down into layers one atom thick, is very strong, chemically stable and an excellent conductor of electricity.
To make their uniquely compact electrode, Professor Li’s team exploited an adaptive graphene gel film they had developed previously. They used liquid electrolytes - generally the conductor in traditional SCs - to control the spacing between graphene sheets on the subnanometre scale. In this way, the liquid electrolyte played a dual role: maintaining the minute space between the graphene sheets and conducting electricity.
Unlike in traditional ‘hard’ porous carbon, where space is wasted with unnecessarily large ‘pores’, density is maximised without compromising porosity in Professor Li’s electrode.
To create their material, the research team used a method similar to that used in traditional papermaking, meaning the process could be easily and cost-effectively scaled up for industrial use.
“We have created a macroscopic graphene material that is a step beyond what has been achieved previously. It is almost at the stage of moving from the lab to commercial development,” Professor Li said.
The work was supported by the Australian Research Council.
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