Bugpower, the energy of the future

A farewell bleep, then a blank screen … your mobile phone, on which your work and social life depend, has become a useless lump of plastic and silicon: the battery is dead.

Sugar-eating bacteria could power tomorrow's mobile phones

No problem.

Just reach for the nearest bowl of sugar, flip open the phone, top up the battery with a wee spoonful, give it a little time – and hey presto, you are connected to the world again.

This sci-fi scenario may lie in the not-too-distant future, thanks to a pair of US-based scientists who say they have invented the world’s first efficient “bacterial battery.”

In a Pentagon-backed project, University of Massachusetts researchers Swades Chaudhuri, an Indian, and Derek Lovley, an American, say the battery’s source is an underground bacterium that gobbles up sugar and converts its energy into electricity.

Their prototype device ran flawlessly without refuelling for up to 25 days and is cheap and stable.

“This is a unique organism,” Lovley told AFP in an interview, as he outlined an array of potential applications.

Underground bug

Microbial fuel cells are not new, but until now they have run into big problems of cost and energy efficiency.

The bug in question is Rhodoferax ferriducens, which was found in airless sediment deep below ground at a terrestrial site at Oyster Bay, Virginia, and identified as a promising candidate for oxidising simple sugars.

The two scientists, whose work is published on Sunday in the specialist journal Nature Biotechnology, set up a small two-chambered vessel, with each side containing a graphite electrode and separated by a membrane.

On one side was R ferriducens swimming in a glucose solution, which it broke down into carbon dioxide (CO2) and electrons.

The electrons were transported to the nearby electrode, called the anode, and driven around an external circuit to the other electrode, the cathode: electrical power.

Microbial fuel cells are not new, but until now they have run into big problems of cost and energy efficiency.

Typically, they yield efficiency of “10% or less,” which makes them big and unwieldy relative to the power they provide, Lovley said.

The best effort has had an efficiency performance of about 50%.

But this was only achieved thanks to chemicals called mediators which sneak across the cell’s membranes, pick up the free electrons and ferry them to the anode.

The mediators are expensive and have to be replenished frequently, and this makes them unsuitable as a simple, long-term energy source.

Sucrose from cane sugar suits the bugs fine
Sucrose from cane sugar suits the bugs fine

Sucrose from cane sugar suits the bugs fine

The prototype made by Lovley and Chaudhuri cranks out only a tiny amount of current – enough to run a calculator or Christmas tree lights.

But as a proof of concept it is remarkable.

Its energy efficiency is an extraordinary 83%, which implies that, if engineering obstacles can be overcome and manufacturing techniques devised, it could one day be as compact as household batteries.

It worked not only with glucose but also with the fruit sugar fructose, with sucrose (found in sugar cane and sugar beet) and even xylose, a sugary by-product of wood and straw.

In addition, the bacterium is rugged and stable, able to grow at temperatures ranging from four to 30C (39.2 to 86F), with 25C (77F) the optimum.

Sewage power

All of the fuel is used up. The process does have a pollutant, in the form of CO2, which is a greenhouse gas, but the contribution to global warming would be far less than the equivalent emission using fossil fuel, says Lovley.

“In the short term, I see the usefulness would be for charging up batteries that can be used in a cell phone, something like that,” said Lovley.

The technology could also be used in environments where it is difficult or costly to charge the batteries, he said, explaining that the US Department of Defence was interested in it for powering underwater microphones and sonar to spot passing ships and submarines.

And, for people living in poor, remote communities, it should be possible to adapt the electrodes so that they use carbohydrate waste from farm animals or sewage to power batteries for running fridges and stoves.

Source: News Agencies