Well, maybe it's not quite this electrifying, but the electrochemical cell prototype is pretty cool. Florian F. (Flowtography)/Flickr, CC BY-NC-ND
By Tessa Evans, The Conversation
Picture a device that can produce electricity using nothing but the ambient heat around it.
Thanks to research published in the Proceedings of the National Academy of Science today, this scenario is a step closer – a team from MIT has created an electrochemical cell which uses different temperatures to convert heat to electricity.
The cell only needs low-grade waste heat – less than 100C – to charge batteries, and is a significant step forward compared to similar devices which either require an external circuit for charging or high temperature heat sources (300 C).
“It’s a great idea to be able to recover useful electrical energy from waste heat,” Anthony Vassallo, Delta Electricity Chair in Sustainable Energy Development at The University of Sydney, said.
At higher temperatures (60C), the cell (which is made of Prussian blue nanoparticles and ferrocyanide) was charged, and following cooling to 15C, the cell discharged energy. At lower temperatures the cell discharged more energy than was used to charge it, so converted heat to electricity.
Gang Chen, CC BY
The amount of heat energy generated is dependent on the temperature and the Carnot limit. The Carnot limit is the maximum absolute amount of heat energy that can be converted to useful electricity.
In cars, engine heat efficiency has reached around 20%, while the Carnot limit – the absolute efficiency which could be reached at that operating temperature – is 37%.
This means that most heat energy conversion is based on high temperature, and low-grade heat conversion devices will never be able to achieve high conversion efficiencies.
This first prototype can only convert 2% heat energy to electricity, and, Professor Vassallo predicted, will have a Carnot limit of “less than 10%”.
“While this will no doubt be improved, there are thermodynamic limits which basically say the maximum efficiency will always be low at the sort of temperatures these electrochemical cells could work at,” he said.
Tao Zero/Flickr, CC BY-NC-SA
When dealing with such low conversion efficiencies (generating watts rather than kilowatts), Damon Honnery – a research engineer at Monash University – said that “overcoming system losses can be a significant technical barrier".
But it’s not all bad, according to Professor Honnery: “There is a demand for low power sources. Lots of electrical systems require low power, and there could be niche uses for smaller devices where the energy density doesn’t need to be so high.”
On the road to application
The researchers want to try use the technology to harvest heat from the environment in remote areas. But as solar arrays already dominate the market, and operate more efficiently, it is unlikely heat conversion technology will supersede them any time soon.
And as the heat conversion battery needs two temperatures to operate, the battery would require fairly extreme fluctuations in temperature in order to function outside the laboratory.
While this would be easy over long 24-hour cycles, rapid discharging is unlikely, so the amount of electricity generated over a day would be small.
Adam Best, a senior research scientist at CSIRO, said, “like all things in batteries, it’s a materials science challenge. Can you get better materials which are able to convert this heat in a more efficient fashion?”
Dr. Best suggested the technology may be better used in industrial facilities or in tandem with other energy systems to further enhance energy production.
Tessa Evans is Editor at The Conversation. Damon Honnery is an Associate Professor, Department of Mechanical Engineering at Monash University. Adam Best is a Senior Research Scientist at CSIRO. Anthony Vassallo is Delta Electricity Chair in Sustainable Energy Development at University of Sydney. This article was originally published on The Conversation. Read the original article.