The bacteria can load electrons onto and discharge electrons from microscopic particles of magnetite, researchers said.
This discovery holds out the potential of using this mechanism to help clean up environmental pollution, and other bioengineering applications, they said.
"The geochemistry is interesting in itself, but there are also potentially useful implications which may derive form this work," said study leader Dr James Byrne from the University of Tubingen, Germany.
The flow of electrons is critical to the existence of all life and the fact that magnetite can be considered to be redox active opens up the possibility of bacteria being able to exist or survive in environments where other redox active compounds are in short supply in comparison to magnetite.
Researchers from Tubingen, the University of Manchester, and Pacific Northwest National Laboratory, US, incubated the soil and water dwelling purple bacteria Rhodopseudomonas palustris with magnetite and controlled the amount of light the cultures were exposed to.
Using magnetic, chemical and mineralogical analytical methods, the team showed that in light conditions which replicated the day-time, phototrophic iron-oxidising bacteria removed electrons from the magnetite, thereby discharging it.
This oxidation/reduction mechanism was repeated over several cycles, meaning that the battery was used over repeated day-night cycles.
Whilst this work has been on iron-metabolising bacteria, it is thought that in the environment the potential for magnetite to act as a battery could extend to many other types of bacteria which do normally not require iron to grow, e.G. fermenters.
The study was published in the journal Science.