Turning golf into power

In an effort to boost renewable energy production and diversify its energy sources in the wake of the Fukushima disaster in 2011, Japan is covering its many abandoned old courses in solar panels.

During Japan’s boom years, golf courses spread like a rash across the country, but when the bubble burst, many were unable to keep up with the huge costs associated with running a golf course on one of the world’s most densely-populated islands.

As a result, many lie abandoned, but renewable energy companies are seeing their potential as sources of power.

Multinational company Kyocera last week announced that they have started construction on a 23-megawatt ‘solar farm’, on a former golf course in Kyoto prefecture.

It’s due to start operating in September 2017, and will generate an estimated 26,312 megawatt hours every year – that’s enough electricity to power around 8,100 typical households in the area.

Kyocera and other companies are also developing an even bigger solar power plant, at another abandoned golf course in Kagoshima prefecture. This one’s set to open in 2018, and will produce almost four times as much power as its predecessor.

There’s hundreds of similar sites across Japan, owing to a severe over-development of golf courses in the past.

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Origami battery

Origami, the Japanese art of paper folding, can be used to create beautiful birds, frogs and other small sculptures. Now a Binghamton University engineer says the technique can be applied to building batteries, too.

Seokheun “Sean” Choi developed an inexpensive, bacteria-powered battery made from paper, he writes in the July edition of the journal Nano Energy.

The battery generates power from microbial respiration, delivering enough energy to run a paper-based biosensor with nothing more than a drop of bacteria-containing liquid. “Dirty water has a lot of organic matter,” Choi says. “Any type of organic material can be the source of bacteria for the bacterial metabolism.”

The method should be especially useful to anyone working in remote areas with limited resources. Indeed, because paper is inexpensive and readily available, many experts working on disease control and prevention have seized upon it as a key material in creating diagnostic tools for the developing world.

“Paper is cheap and it’s biodegradable,” Choi says. “And we don’t need external pumps or syringes because paper can suck up a solution using capillary force.”

While paper-based biosensors have shown promise in this area, the existing technology must be paired with hand-held devices for analysis. Choi says he envisions a self-powered system in which a paper-based battery would create enough energy — we’re talking microwatts — to run the biosensor. Creating such a system is the goal of a new three-year grant of nearly $300,000 he received from the National Science Foundation.

Choi’s battery, which folds into a square the size of a matchbook, uses an inexpensive air-breathing cathode created with nickel sprayed onto one side of ordinary office paper. The anode is screen printed with carbon paints, creating a hydrophilic zone with wax boundaries.

Total cost of this potentially game-changing device? Five cents.

Choi, who joined Binghamton’s faculty less than three years ago as an assistant professor of electrical and computer engineering, earned a doctorate from Arizona State University after doing undergraduate work and a master’s degree in South Korea. Choi, who holds two U.S. patents, initially collaborated on the paper battery with Hankeun Lee, a former Binghamton undergraduate and co-author of the new journal article.

Choi recalls an actual “lightbulb moment” while working on an earlier iteration of the paper-based batteries, before he tried the origami approach. “I connected four of the devices in series, and I lit up this small LED,” he says. “At that moment, I knew I had done it!”

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