Sign In

Communications of the ACM

ACM News

Nanotube Thermopower


View as: Print Mobile App Share: Send by email Share on reddit Share on StumbleUpon Share on Hacker News Share on Tweeter Share on Facebook

When weighing options for energy storage, different factors can be important, such as energy density or power density, depending on the circumstances. Generally batteries—which store energy by separating chemicals—are better for delivering lots of energy, while capacitors—which store energy by separating electrical charges—are better for delivering lots of power (energy per time). It would be nice, of course, to have both.

Michael Strano and his colleagues at MIT are working to store energy in thin carbon nanotubes by adding fuel along the length of the tube, chemical energy, which can later be turned into electricity by heating one end of the nanotubes. This thermopower process works as follows: the heat sets up a chain reaction, and a wave of conversion travels down the nanotubes at a speed of about 10 meters/second.

Strano reports the efforts in "New Concepts in Molecular and Energy Transport Within Carbon Nanotubes: Thermopower Waves and Stochastically Resonant Ion Channels," presented Tuesday (Oct. 19) at the  AVS 57th International Symposium & Exhibition.

"Carbon nanotubes continue to teach us new things—thermopower waves as a first discovery open a new space of power generation and reactive wave physics," Strano says.

A typical lithium ion battery has a power density of 1 kW/kg. Although the MIT researchers have yet to scale up their nanotube materials, they obtain discharge pulses with power densities around 7 kW/kg.

Strano will also be reporting new results on experiments exploiting carbon nanopores of unprecedented size, 1.7 nanometers in diameter and 500 microns long.

"Carbon nanopores," he says, "allow us to trap and detect single molecules and count them one by one," the first time this has been done. And this was at room temperature.

The single molecules under study can move across the nanotubes one at a time in a process called coherence resonance. "This has never been shown before for any inorganic system to date, but it underpins the workings of biological ion channels," Strano says.


 

No entries found