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Article Released Mon-23rd-April-2018 08:00 GMT
Contact: Mikiko Tanifuji Institution: National Institute for Materials Science
 The green nanotechnology revolution [Asia Research News 2018 feature]

Nanocellulose offers renewable, biodegradable, strong and lightweight components for electronic products.

Image Name
Portable solar cells based on foldable, lightweight, transparent, conductive cellulose nanofibre paper.
Copyright : CC-BY Macmillan Publishers Ltd
Imagine folding up a paper-thin computer tablet like a newspaper. Such flexible electronics are moving closer to reality, according to a review in the journal Science and Technology of Advanced Materials.

Paper that is transparent and conducts electricity could have diverse applications, including foldable computers, transparent touch screens and even digital camouflage clothing. “With widespread and intensive efforts, low-cost and lightweight ‘green’ electronics fabricated on transparent nanopaper substrate will provide new technologies impacting our daily life,” state the review paper authors from Nanyang Technological University in Singapore.

Cellulose, the building block of paper taken from plants, is an exciting alternative to the plastic, glass and silicon that currently make up most electronic devices, including computers and mobile phones. Cellulose is renewable, biodegradable, strong and lightweight. For the past 30 years, scientists have considered ways to combine the smallest plant fibres, called ‘nanocellulose’, with electronics.

For example, researchers at Nanyang Technological University have made nanopaper out of nanocellulose and silver nanowires. It still conducts electricity after being folded in half 500 times. Some nanopapers have reached 90% transparency, while others are in the 80% range similar to plastic.

But, better than plastic, nanopapers degrade quickly. After metal electrodes are removed, nanopaper can be buried in soil and will fully degrade within a month. However, this benefit is also a challenge: researchers are working on ways to prevent premature degradation. If they can solve this as well as bring down production costs, electronics could soon be built from plants.

Preventing the ‘coffee ring’ effect

Nanocellulose can also enhance ink and printed electronics, which are produced much like printed words, by helping particles disperse evenly rather than spread apart.

Drying is an important part of printing words and electronics. Particles suspended in liquid are applied to a surface and the liquid evaporates leaving the particles behind. Often, the particles dry unevenly because of the so-called ‘coffee ring effect’. Particles tend to move to the outside of the liquid droplet, similar to the hollow rings left by dried, spilled coffee.

Uneven drying is a problem: it reduces conductivity of printed electronics, accelerates degradation of paint coatings, and makes printed characters on paper fuzzier. Cellulose nanofibres offer a sustainable and effective way to ensure even drying, according to another paper published in Science and Technology of Advanced Materials.

Research by Tokyo University of Agriculture and Technology and Nagoya University found that liquids with nanofibres dried much more evenly than those without. Instead of a hollow ring, the particles condensed into a solid dot, slightly shrinking in size as the liquid evaporated. Particles in the mixtures with nanofibres also moved at a consistent pace. There was no final rush to the periphery as was observed in liquids without nanofibres.

Further investigation is required to determine how the nanofibres, which remain after drying, affect material performance. “The addition of cellulose nanofibres may alter the electrical resistivity of conductive wires in the printed electronics, but the fine-tuning of the concentration might be exploited for the control of electric resistivity itself,” the researchers conclude.

Further information
Professor Pooi See Lee | E-mail: pslee@ntu.edu.sg
School of Materials Science and Engineering
Nanyang Technological University

Associate Professor Itsuo Hanasaki | E-mail: hanasaki@cc.tuat.ac.jp
Institute of Engineering
Tokyo University of Agriculture and Technology
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A dried liquid without nano cellulose fibres (left) formed a ring, similar to dried, spilled coffee, while a liquid with fibres (right) dried more evenly.
Copyright : CC-BY Macmillan Publishers Ltd

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