Scientists from Australiaโs national science agency, CSIRO, have led an international team to a clean energy breakthrough by setting a new efficiency record for fully roll-to-roll printed solar cells.
Printed onto thin plastic films, this lightweight and flexible solar technology will help meet the growing demand for renewable energy by expanding the boundaries of where solar cells can be used.
Where silicon solar panels are rigid and heavy, the printed solar cells are highly flexible and portable, meaning they can be deployed in previously unimaginable ways acrossย construction, mining, space, defence and personal electronics.
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CSIROโs renewable energy systems group leader Dr Anthony Chesman said the achievement was the result of more than a decadeโs research and development.
โCSIROโs thin and light-weight solar cells are now on the cusp of emerging from the lab to create clean energy in the real world,โ Dr Chesman said.
โWeโve solved several engineering problems to achieve record results across a large surface area of interconnected modules.
โRoll-to-roll printing allows for the solar cells to be manufactured on very long, continuous rolls of plastic, which can dramatically increase the rate of production.
โAs these methods are already widely used in the printing industry, this makes their production more accessible for Australian manufacturers.
โThe successful commercialisation of printed flexible solar cells has the potential to create significant economic and environmental benefits for Australia and the world,โ he said.
The results were achieved in collaboration with researchers from the University of Cambridge, Monash University, the University of Sydney and the University of New South Wales, and have been published in the leading journal Nature Communications.
Lead author and CSIRO principal research scientist Dr Doojin Vak said an automated system produced a comprehensive dataset that would pave the way to use machine learning in future research.
โWe developed a system for rapidly producing and testing over ten thousand solar cells a dayโsomething that would have been impossible to do manually,โ Dr Vak said.
โThis allowed us to identify the optimal settings for the various parameters in the roll-to-roll process and quickly pinpoint the conditions that deliver the best results,โ he said.
Incorporating an advanced material called perovskite, CSIROโs printed solar is different from the silicon solar panels found on Australian roofs.
โPerovskites are a class of emerging solar cell material. Theyโre remarkable because they can be formulated into inks and used in industrial printers,โ Dr Vak said.
โWe’ve also alleviated the need to use expensive metals, such as gold, in their production by using specialised carbon inks, which further reduces production costs,” he said.
Acknowledging that perovskite solar cells currently trail silicon solar panels in efficiency and lifetime when produced at scale, Dr Chesman sees the application of flexible panels to be very different.
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“As these perovskite solar cells are printed onto plastic films, they are very lightweight, highly flexible and portable,โ he said.
โThe rigidity and weight of conventional silicon solar panels can make moving them difficult. Our thin, lightweight solar can be easily transported anywhere there is sun.
โWe even sent the solar panels to space last week to test their performance, with a view to further optimise and ultimately provide a reliable energy source for future space endeavours,โ Dr Chesman said.
CSIRO is seeking industry partners to further develop and commercialise this technology.