Rhitu Chatterjee

Rhitu Chatterjee

Rhitu Chatterjee is a science correspondent for The World.

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How Plantain Trees Could Become an Energy Source

August 22, 2012 Post a comment

About a quarter of all people worldwide live without electricity. For them, evenings and nights are spent by candlelight or kerosene lamp.

But some scientists in Sri Lanka say they have found a way to bring simple electric lighting to rural people in that part of the world.

It begins with a homegrown battery developed by K.D. Jayasurya, a physicist at Sri Lanka’s Kelaniya University.

Just a few blocks from Jayasurya’s laboratory stands a small patch of trees.

“These are the plantain trees,” he says, and points to bunches of green, unripened fruit hanging down from the branches.

Plantains are a popular food here in Sri Lanka, and most people grow the fruit in their own yards, especially in rural areas. These are also places with little or no access to electricity.

About a year ago, Jayasurya and his colleagues got an idea: Could they use the plantain trees to make batteries for Sri Lanka’s rural poor?

“If we can produce a cell with freely available raw material which is biodegradable, then they can use that to light their houses,” he says. “It can add value to their life.”

The idea of using plant material to make battery cells isn’t new.

Potato-powered batteries are a common science experiment in American schools. The potato contains an acid that reacts with metal electrodes, causing electrons to flow and generating an electric current.

Several years ago, Israeli scientists found a way to boost the power of potato batteries so that they could be used to run light bulbs and other simple household devices.

Plantains are available throughout the year. People cut the stems to harvest the fruit, then leave the tree trunks to decay. (Photo: Rhitu Chatterjee)

Plantains are available throughout the year. People cut the stems to harvest the fruit, then leave the tree trunks to decay. (Photo: Rhitu Chatterjee)

But potatoes aren’t cheap in Sri Lanka, so Jayasurya and his team wanted to see if they could use plantain trees as the raw material. Once the fruit is harvested, the rest of the tree becomes waste, which means there’s plenty of material available all over Sri Lanka.

Nandan Jayashantha, a student on Jayasurya’s team, demonstrates how to make the battery.

He takes a piece of plantain trunk and tears off the outer layers to get to the central-most part. After extracting the core, he boils it and then chops it finely until it turns into a soft mushy material.

Jayashantha then takes some of that material and stuffs it between two rectangular pieces of metal that are held in place by bright yellow electrical tape. The two pieces of metal are the battery’s electrodes.

“We used copper and zinc electrodes,” he says.

The electrodes react with phosphoric acid from the plantain tree, creating an electric current.

The electrical output of each battery is tiny – just seven tenths of a volt – but when Jayashantha places four of these cells in a row and connects them, the output is enough to light up a big LED.

The team still has a long way to go before people in rural communities can use these batteries to light up their homes, but the aim is to create something that rural consumers can make with a small investment in equipment.

One advantage of the technology is that a single cell can last a long time.

“Once you make the cell, you can use it for about ten days’ continuous lighting,” says Ruwan Wijesundara, another physicist at the University of Kelaniya, and a collaborator on the project.

An average tree has enough material for thirty to forty such cells, which means the waste of one plantain tree could someday light a bulb for a whole year.


Discussion

8 comments for “How Plantain Trees Could Become an Energy Source”

  • http://www.facebook.com/david.gustavson David Gustavson

    But the metal electrodes are consumed, right? What do they cost, and how available are they?

    • http://www.facebook.com/rhitu Rhitu Chatterjee

      Hi David, This is Rhitu Chatterjee, the reporter on this piece. Thanks for your questions. I’m not sure how much the electrodes cost, but I was told they’re pretty cheap and definitely cheaper than all the money people spend on kerosene (for their lamps) everyday. Also, the scientists say that when this technology is ready for commercial use, they would have to hand the technology to the right people/NGO, who can ensure that the electrodes are affordable and available for use by rural communities. I’ve asked the scientists to respond to your question too. So you should be hearing from them soon.

  • http://www.facebook.com/people/Howard-Christofersen/100000886030808 Howard Christofersen

    “bunches of green, unripened fruit hanging down from the branches.” There are no branches, The trunk is formed by the stems of the leaves. The fruiting stem comes up the middle and then hangs down from the weight of the fruit. We had both plantains and bananas in our garden where I grew up in S. Africa.

  • Nils Erickson

    Here’s another inexpensive battery construction technique using pennies, cardboard, vinegar and aluminum foil. http://www.youtube.com/watch?v=Ur9934-IFBs

  • RRRRRzzzzz

    Wow! I can’t tell whether the article is scientifically illiterate, or principals need to re-read their chemistry texts. The cell’s electrical energy comes entirely from oxidizing the zinc electrode. All that energy was originally put into the zinc at the point of its manufacture by burning coal or petroleum. This idea has nothing whatsoever to do with using abundant plantain pulp as an energy source.

    Seems much simpler to put the electrodes into a used pop bottle with water and acidic juice, and be done with it. I suppose the pulp could be acting as a cation barrier. But the way this article is spun, it’s impossible to tell what the pulp’s advantage is over a different reusable design that would more efficiently extract the energy from the zinc electrode.

    As Dave G points out, the primary issue is who pays for the electricity stored in the zinc, and how is that zinc made available to the rural residents.

  • Lorne Temes

    David Gustavson is right, & so is RRRRzzzz. The energy is not coming from the plants & photosynthesis. It`s coming from the refined metals becoming ionized (and the cathode`s ions dissolve in the electrolyte, thus the cathode is consumed), and the energy-profligate processes of refining the metals from their ores are not green at all. All in all, it has the odor of a hype-storm generated by publicists. All the same, knowing how to do these things might be useful in a ruined world if we need to eke out an existence by cannibalizing the leftover products that remain.

  • http://www.facebook.com/people/Malcolm-Sequeira/635361984 Malcolm Sequeira

    How much energy is used to boil the inner part of the tree?

    • Ruwan Wijesundera

      We are at the initial stage of the Zn/Cu-plantain
      pith Galvanic cell investigation and results reveal the possibility of lighting
      LED system. Still we did not carry out proper analysis of the durability of Zn
      electrodes and the cost of the power generation. Zn/Cu-potato Galvanic cells were
      well investigated and reported in the literature (A. Golberg et al, J.
      Renewable Sustainable Energy 2, 033103, 2010). Zn/Cu-boiled
      potato battery generates energy at 9 USD/kWh, which is 50-fold cheaper than the
      currently available 1.5 V AA alkaline cell according to their primary cost
      analyses. Plantain pith is a comparative electrolytic material for the potato
      and power generation of the battery is almost similar to the Zn/Cu Potato
      Galvanic cell. Since the plantain pith is freely available in Sri Lanka after the plantain yield, Zn/Cu-plantain pith battery should generate energy at very low cost than 9 USD/kWh.