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January 14, 2008
Volume 86, Number 2
p. 12


Thermoelectric Materials

Silicon nanowires transform heat into electricity

Bethany Halford

Benjamin Utley
Artist's rendition of a silicon nanowire suspended between two heating pads.

By forming silicon into discrete nanostructures, scientists have managed to transform the element from a poor thermoelectric material into a good one. The result could lead to inexpensive, energy-salvaging devices that harvest wasted heat and turn it into electricity.

Thermoelectric materials convert temperature gradients into voltages and vice versa. If one end of such a material is hot and the other is cold, a voltage is generated, which can then be used to create electrical power.

For a material to have good thermoelectric properties, however, it must be a good electrical conductor and a poor thermal conductor. Because bulk silicon is good at conducting both electricity and heat, scientists had ruled it out as a possible thermoelectric material. Two teams have now independently discovered that by nanostructuring silicon, they can reduce its thermal conductivity, making the material promising for thermoelectric applications (Nature 2008, 451, 163 and 168).

Groups led by Peidong Yang, of the University of California, Berkeley, and James R. Heath, of Caltech, both found that nanowires made of silicon have thermoelectric efficiencies that are comparable with those of the best commercial thermoelectric materials. According to Heath, nanostructuring also seems to confer drag upon the material's heat-propagating waves, or phonons, thereby improving its thermoelectric efficiency.

"Silicon is one of the most abundant elements, and there is already a multi-billion-dollar infrastructure for low-cost and high-yield processing behind it," Yang says. Compared with the best commercial thermoelectrics made of materials such as Bi2Te3, he adds, silicon is easier to process, less expensive, and environmentally benign.

Silicon thermoelectrics could also be easier to integrate into other silicon-based systems, Heath notes. "Having thermoelectrics that can be harnessed to recover heat generated by a microprocessor and fabricated on the same chip as the microprocessor could be extremely useful," he says. For example, laptop computer batteries get hot, and "that heat could potentially be recovered," Heath says.

Both Yang and Heath say that some engineering work is needed before their silicon nanowire thermoelectrics find practical applications, but Mercouri G. Kanatzidis, a thermoelectrics expert at Northwestern University, believes that they're on the right track. "It confirms a growing sense in the science community that proper nanostructuring of materials will yield very significant enhancements in thermoelectric performance," he says.

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Chemical & Engineering News
ISSN 0009-2347
Copyright © 2009 American Chemical Society


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