Industries in Depth

This unexpected material could be the future of electronics

Renesas Electronics Corp's microcontroller chips are seen in this illustrative photograph taken in Tokyo May 24, 2012. Japan's loss-making Renesas Electronics Corp said on Thursday it will tie up with Taiwan Semiconductor Manufacturing Co in the microchip business as it struggles to keep up with aggressive rivals like Samsung Electronics.   REUTERS/Kim Kyung-Hoon  (JAPAN - Tags: BUSINESS SCIENCE TECHNOLOGY) - GM1E85O1M4D02

They’re flexible, sustainable, friendly to the environment, and low-cost. Image: REUTERS/Kim Kyung-Hoon

Seokheun Choi
Associate Professor of Electrical and Computer Engineering, Binghamton University, State University of New York

It seems like every few months there’s a new cellphone, laptop or tablet that is so exciting people line up around the block to get their hands on it. While the perpetual introduction of new, slightly more advanced electronics has made businesses like Apple hugely successful, the short shelf life of these electronics is bad for the environment.

Modern electronics are filled with circuit boards on which various metals and plastics are soldered together. Some of these materials are toxic – or break down into toxic substances. There are efforts underway to boost recycling of e-waste, recovering materials that can be reused and properly disposing of the rest. But most devices end up added to the growing piles of e-waste in landfills.

Instead of adding more trash to these ever-growing piles, there is an opportunity to create electronics that are biodegradable. That’s why other researchers and I are looking to the emerging field of paper-based electronics – known as “papertronics.” They’re flexible – even foldable – sustainable, friendly to the environment and low-cost.

But to be truly eco-friendly, papertronics can’t use traditional batteries, which are made of metals and caustic acids, to store and discharge electricity. Recently, my chemist colleague Omowunmi Sadikand I developed a paper battery that’s recyclable and biodegradable, as well as reliable enough to actually use. The key is bacteria.

Flexible bio-batteries

I’ve developed flexible batteries, batteries powered by saliva and more. I figured that when seeking to power paper-based electronics, it made sense to try to make a battery out of paper. Fortunately, paper is a good potential battery material: It’s flexible, a good insulator – which makes it a good platform for mounting electronic components on – and absorbs and releases fluids easily. We added polymers – poly (amic) acid and poly(pyromellitic dianhydride-p-phenylenediamine) – to improve those electrical characteristics.

Then, to store energy in the battery, in place of the metals and acids that react chemically to generate electrons, we added bacteria. When these batteries are eventually commercialized, they’ll use bacteria that are safe for humans and the environment and well-contained to reduce any other contamination.

Because the paper is rough and porous, the bacteria stick to it, and generate their own energy by breaking down almost any available organic material, including plant material or wastewater. At the moment, we’re prepackaging source material, but it could also come from the environment. This chemical reaction produces electrons. Normally in a bacterial reaction, those electrons would bond with oxygen, but we’ve built our battery to limit oxygen and substitute an electrode, meaning we can capture the electron flow and use it to power devices.

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We were concerned that oxygen could get into the paper and interrupt the electron flow between the bacteria, decreasing the battery’s efficiency. We found that while that does happen, it has minimal effects. That’s because so many bacterial cells are so tightly attached to the paper fibers; they form a multi-layer biofilm that shields the chemical reaction from most oxygen.

We also wanted a battery that could biodegrade. The bacteria in the battery itself, once they’re done releasing energy, can break down the paper and polymers into harmless components. In water, our battery easily biodegraded, without any special equipment or other microorganisms to aid in the breakdown.

The polymer-paper structures are lightweight, low-cost and flexible. That flexibility also allows for the batteries to fold like a normal piece of paper, or be stacked on top of each other. That lets more battery power fit into smaller spaces.

 A group of folded batteries can power a paper-based electronic device.
Image: Seokheun Choi/Binghamton University

Promises and opportunities

Papertronics can be particularly useful in remote areas with limited resources because they’re powered by bacteria that can inhabit even the most extreme of conditions and break down nearly any material to produce electrons. They don’t need a well-established power grid, either. In addition, though paper batteries are designed to be disposable after they’re used, their materials are recyclable – and new batteries can be created from recycled paper.

As revolutionary as paper-based bio-batteries are for future electronic devices, they’re fairly straightforward to make. The polymers and bacteria can be blended with paper in traditional manufacturing processes, including roll-to-roll printing and screen printing – or even be painted or poured right onto paper.

Other materials can also be added to the paper batteries – like metals, semiconductors, insulators and nanoparticles. These and other substances can add more properties and capabilities to paper-based devices, opening new doors for the next generation of electronics.

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