Home > Press > Advance in energy storage could speed up development of next-gen electronics
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| Electronics could shrink even further with the development of new ultrathin capacitors. Credit: airrazab/iStock/Thinkstock |
Abstract:
Electronics are getting smaller all the time, but there's a limit to how tiny they can get with today's materials. Researchers now say, however, that they have developed a way to shrink capacitors — key components that store energy — even further, which could accelerate the development of more compact, high-performance next-gen devices. The study appears in the journal ACS Nano.
Advance in energy storage could speed up development of next-gen electronics
Washington, DC | Posted on February 19th, 2014Takayoshi Sasaki and colleagues point out that many recent improvements have already downsized capacitors significantly. But current technology has almost reached its limit in terms of materials and processing, which in turn limits the performance that manufacturers can achieve. In response, researchers have gone to the nanoscale, but "nanocapacitors" are not easy to make.
They require harsh, difficult-to-use methods and even then, they may not work that well. So Sasaki's team developed an easier approach, and they use it to make high-performance "ultrathin" capacitors.
The researchers found that they could use gentle techniques and mild conditions to create a sandwich consisting of layers of two different types of oxide nanosheets to produce an ultrathin capacitor. In addition, the new capacitor has a capacitance density about 2,000 times higher than that of commercially available products. They say that, in the future, the ultrathin capacitors could be used in printed circuit boards and in memory storage devices, for example.
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The authors acknowledge funding from the Japan Science and Technology Agency and MEXT, Japan.
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About American Chemical Society
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Contacts:
Michael Bernstein
202-872-6042
Takayoshi Sasaki, Ph.D.
International Center for Materials Nanoarchitectures
National Institute for Materials Science
1-1 Namiki
Tsukuba
Ibaraki 305-0044
Japan
Copyright © American Chemical Society
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