Chemists in Germany have figured out a way to extract energy from just water and oxygen

Chemists in Germany have figured out a way to extract energy from just water and oxygen. The discovery uses existing fuel cell technology and minimal additional chemicals, providing a safer way to generate electricity for low-power applications.

What did they do?

The authors purchased a commercially available fuel cell, the kind that would ordinarily be used to harvest power from methanol, an energy carrier chemical commonly used in fuel cells. They poured water into the anode side of the cell. The cathode side was exposed to a temperature-controlled stream of air.

What did they find?

The fuel cell was driven by evaporation of water from one end of the cell, “pulling” the chemical reactions forward. This form of entropy powered the cell.

Considering the chemical reactions involved, at one end of the cell, water breaks down to make oxygen, hydrogen ions, and electrons. At the other end of the cell, the oxygen, hydrogen ions and electrons recombine to make water. In other words, the chemical input (water) is the same as the output. The net enthalpy, or heat balance, is zero, because any heat released at one side of the cell would be balanced by an equal absorption of heat at the other side, so release of heat cannot be the driving force for the fuel cell.

However, this fuel cell used two different forms of water: liquid and vapor. Liquid water is fed into the cell and vapor escapes. Vapor is more disordered than liquid, so the entropy increases and the chemical reaction moves forward. The electrons are forced through a circuit in the process, to make electricity.

What does it mean?

This paper reports a unique approach in developing fuel cells. It takes advantage of the fact that a chemical reaction can be "downhill" or spontaneous even if no heat is released, as long as there is an increase in entropy.

The fuel cell design reported in this study uses this technique to drive the overall chemical reaction.

Remarkably, the fuel cell setup can be used to generate electricity from water and air, producing just water and oxygen as byproducts. This is extremely attractive compared to hydrogen, methanol or other common fuel cell chemicals that only carry energy that was generated elsewhere. For example, it is possible to derive hydrogen from solar or wind power, but in practice most hydrogen comes from natural gas or oil, and a fuel cell would only be capturing the energy from those non-renewable sources.

In addition, the use of water as the energy source avoids problems of flammability and toxicity. Many existing fuel cell technologies based on liquids have the drawbacks that the fuels, byproducts or sometimes both are very hazardous. For example, methanol fuel cells can produce formaldehyde, a cancer-causing chemical. The authors noted that high pH gave better results; in other words the use of a pH-raising additive like sodium hydroxide would be necessary to give optimum performance. This could be considered a drawback but it might be possible through further research to improve the reaction rate by other means.

Because evaporation of water is critical to the process, the researchers suggested that the technology would be most effective in dry, windy areas.

The main limitation of the water fuel cell is that it needs more space, and materials, to generate the same amount of power as a denser fuel cell. The researchers suggest that the water fuel cell is perhaps 100 times less dense than would be practical for most applications. The performance, though, is similar to fuel cells that produce electricity from microbial activity. The researchers suggest the cell would be adequate to power sensors or wireless transmitters.

Further research on these fuel cells might compare the amount of energy used to construct the fuel cell and its component parts, including membranes and metal catalysts, to the amount of energy that could be generated in the fuel cell's expected lifetime.