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Scientists at the National Laboratory (LLNL) and the University of California, Inc.
announced the first ultra-light graphene gel to 3D print supercapacitors, opening the door
for product designers to use efficient energy storage systems for smartphones, wearables, implantable devices, electric vehicles and wireless sensors more freely and without design restrictions.
It is understood that LLNL's research team used a 3D printing process known as direct ink writing and graphene oxide composite inks of the lab's own design to print microstructures, creating supercapacitors that can retain energy, 10 to 100 times
thinner than similar capacitors currently made using electrodes.
This technology breaks through the limits of
2D manufacturing.
Scientists at the National Laboratory (LLNL) and the University of California, Inc.
announced the first ultra-light graphene gel to 3D print supercapacitors, opening the door
for product designers to use efficient energy storage systems for smartphones, wearables, implantable devices, electric vehicles and wireless sensors more freely and without design restrictions.
It is understood that LLNL's research team used a 3D printing process known as direct ink writing and graphene oxide composite inks of the lab's own design to print microstructures, creating supercapacitors that can retain energy, 10 to 100 times
thinner than similar capacitors currently made using electrodes.
This technology breaks through the limits of
2D manufacturing.
