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Researchers from Japan’s Riken Center for Emergent Matter Science have fabricated an organic solar cell that has achieved waterproofness without reducing flexibility. At 3 micrometers thick, it is thought to be the first cell of its kind to survive a washing machine cycle and retain efficiency after multiple cycles.
Researchers from the Riken Center for Emergent Matter Science in Japan have fabricated a waterproof and flexible organic photovoltaic (OPV) solar cell that can be used in wearable electronics.
The team’s cell consists of an in-situ growth of a hole-transporting layer to strengthen interface adhesion between the active layer and anode. The anode layer, in this case a silver electrode, was deposited directly onto the active layers, and then put through a thermal annealing process, exposing the film to air at 85 degrees celsius for 24 hours. This created better adhesion between the layers than typically found in photovoltaic film, thus improving the waterproofness. Sixing Xiong, the first author of the paper, said via this method, the team was able to create a film that was three micrometers thick.
The researchers recorded a champion efficiency of 14.3% under one sun illumination for their cell, which according to their research paper, “outperforms existing waterproof organic photovoltaics”.
The team then tested their cell by immersing it completely in water for four hours and found it still had 89% of its initial performance. When subjecting the film to stretching by 30% 300 times underwater, it retained 96% of its performance. The cell was then put through a washing machine cycle and survived, which according to the research paper, is something that has never been reported before for such a thin encapsulation layer.
“The efficiency degradation was limited to just 10% even after subjecting the devices to two washing cycles in a washing machine, each lasting 66?min,” the scientists stated. “These organic photovoltaics offer remarkable stretchability and waterproof properties even with such thin structure, making them well-suited for wearable electronics.”
Kenjiro Fukuda, one of the corresponding authors of the paper, said the team created a method that can be used more generally. “Looking to the future, by improving the stability of devices in other areas, such as exposure to air, strong light, and mechanical stress, we plan to further develop our ultrathin organic solar cells so that they can be used for really practical wearable devices,” he said.
The full findings are available in the study “Waterproof and ultraflexible organic photovoltaics with improved interface adhesion,” published in Nature Communications.
In 2022, another research group at Riken developed heat-shrinkable polymers that can be used to laminate organic photovoltaic devices onto curved surfaces. |