Uniquely-Powered Battery Smaller Than a Credit Card (8/15)
Testing urine can reveal the identity of illnesses, and the new paper battery could allow the sample being tested to also power the diagnostic device.
"We are striving to develop cheap, disposable credit-card sized biochips for disease detection," says Ki Bang Lee, at the Institute of Bioengineering and Nanotechnology in Singapore. "Our battery can be easily integrated into such devices, supplying electricity on contact with biofluids such as urine or blood."
Current biochips need an external reader such as a laser scanner or an external source of power, such as conventional batteries, to perform diagnostic tests. Lee's technology houses both the sensors and the battery on one plastic chip.
This design circumvents many of the problems encountered by researchers attempting to shrink down more conventional battery systems for use with bioMEMS - devices utilising bio-microelectromechanical systems.
"Many researchers have tried to design power sources or batteries for systems or bioMEMS devices. However, they have done this by reducing the size of conventional, bulky power systems or batteries," explains Lee. "They faced a lot of problems," including difficulties in getting sufficient electrical energy, he adds.
The urine-powered battery was able to generate a voltage of about 1.5 volts - with a corresponding power of 1.5 micro-watts - using just 0.2 millilitres of urine, says Lee. And if a second droplet of urine was added 15 hours after the battery was first activated, the replenished urine could generate still more electricity.
The battery is currently suited for use with disposable devices - it is not yet ready to power laptops or iPods. "But if, for example, we place a small cellular phone or transmitter on a plastic card, the chip will work as a disposable biofluid-activated means of communication in an emergency," Lee told New Scientist. "In this case, the size will be less than that of a credit card."
The battery is made of a layer of filter paper steeped in copper chloride, sandwiched between strips of magnesium and copper. This "sandwich" is then laminated in plastic to hold the whole package together. The resulting battery is just 1 millimeter thick and 60 by 30 mm across - slightly smaller than a credit card.
To activate the battery, a drop of urine is added and soaks through the sandwiched filter paper. The chemicals dissolve and react to produce electricity. The magnesium layer acts as the anode, losing its electrons. And the copper chloride acts as the cathode, mopping up the electrons.
But Lee adds that the voltage, current and capacity of the battery could be improved by different designs or by switching the electrode or electrolyte materials used.
He believes the system could be used in home-based health test kits. "The long-term goal is for people to be able to buy disposable biochips for a disease test from any pharmacy," he says.