James Tour and his colleagues at Rice University have developed a flexible material with nanoporous nickel-fluoride electrodes layered around a solid electrolyte to deliver battery-like super-capacitor performance.
The material combines the best qualities of a high-energy battery and a high-powered super-capacitor without the lithium found in commercial batteries today, researchers said.
The electrochemical capacitor is about a hundredth of an inch thick but can be scaled up for devices either by increasing the size or adding layers, said Yang Yang, co-lead author of the research paper with graduate student Gedeng Ruan.
In tests, they found their square-inch device held 76 per cent of its capacity over 10,000 charge-discharge cycles and 1,000 bending cycles.
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Tour said the team set out to find a material that has the flexible qualities of graphene, carbon nanotubes and conducting polymers while possessing much higher electrical storage capacity typically found in inorganic metal compounds.
Inorganic compounds have, until recently, lacked flexibility, he said.
"Compared with a lithium-ion device, the structure is quite simple and safe," he said.
"It behaves like a battery but the structure is that of a super-capacitor. If we use it as a super-capacitor, we can charge quickly at a high current rate and discharge it in a very short time.
To create the battery/super-capacitor, the team deposited a nickel layer on a backing. They etched it to create 5-nanometre pores within the 900-nanometre-thick nickel fluoride layer, giving it high surface area for storage.
Once they removed the backing, they sandwiched the electrodes around an electrolyte of potassium hydroxide in polyvinyl alcohol.
The finding is detailed in the Journal of the American Chemical Society.