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Nontoxic, flexible energy converters could power wearable devices

Date:
April 27, 2021
Source:
American Institute of Physics
Summary:
Wearable electronics have increasingly become a part of everyday life, so researchers wondered if these could be powered by harvesting electricity from waste heat. Further inspiration came from a desire to ultimately fabricate energy converting devices from the same materials as the active devices themselves. The researchers report the design and fabrication of single-wall carbon nanotube thermoelectric devices on flexible polyimide substrates as a basis for wearable energy converters.
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A wide variety of portable and wearable electronics have become a large part of our daily lives, so a group of Stanford University researchers wondered if these could be powered by harvesting electricity from the waste heat that exists all around us.

Further inspiration came from a desire to ultimately fabricate energy converting devices from the same materials as the active devices themselves, so they can blend in as an integral part of the total system. Today, many biomedical nanodevices' power supplies come from several types of batteries that must be separated from the active portion of the systems, which is not ideal.

In Applied Physics Letters, from AIP Publishing, the researchers report the design and fabrication of single-wall carbon nanotube thermoelectric devices on flexible polyimide substrates as a basis for wearable energy converters.

"Carbon nanotubes are one-dimensional materials, known for good thermoelectric properties, which mean developing a voltage across them in a temperature gradient," said Eric Pop, a professor of electrical engineering and materials science. "The challenge is that carbon nanotubes also have high thermal conductivity, meaning it's difficult to maintain a thermal gradient across them, and they have been hard to assemble them into thermoelectric generators at low cost."

The group uses printed carbon nanotube networks to tackle both challenges.

"For example, carbon nanotube spaghetti networks have much lower thermal conductivity than carbon nanotubes taken alone, due to the presence of junctions in the networks, which block heat flow," Pop said. "Also, direct printing such carbon nanotube networks can significantly reduce their cost when they are scaled up."

Thermoelectric devices generate electric power locally "by reusing waste heat from personal devices, appliances, vehicles, commercial and industrial processes, computer servers, time-varying solar illumination, and even the human body," said Hye Ryoung Lee, lead author and a research scientist.

"To eliminate hindrances to large-scale application of thermoelectric materials -- toxicity, materials scarcity, mechanical brittleness -- carbon nanotubes offer an excellent alternative to other commonly used materials," Lee said.

The group's approach demonstrates a path to using carbon nanotubes with printable electrodes on flexible polymer substrates in a process anticipated to be economical for large-volume manufacturing. It is also "greener" than other processes, because water is used as the solvent and additional dopants are avoided.

Flexible and wearable energy harvesters can be embedded into fabrics or clothes or placed on unusual shapes and form factors.

"In contrast, traditional thermoelectrics that rely on bismuth telluride are brittle and stiff, with limited applications," Pop said. "Carbon-based thermoelectrics are also more environmentally friendly than those based on rare or toxic materials like bismuth and tellurium."

The most important concept in the group's work is to "recycle energy as much as we can, converting uneven heat distribution to electrical energy for use for the next cycle of operation, which we demonstrated by using nontoxic nanotube-based thermoelectric generation," said Yoshio Nishi, a professor of electrical engineering. "This concept is in full alliance with the world's goal of reducing our total energy consumption."


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Materials provided by American Institute of Physics. Note: Content may be edited for style and length.


Journal Reference:

  1. Hye Ryoung Lee, Naoki Furukawa, Antonio J. Ricco, Eric Pop, Yi Cui, Yoshio Nishi. Carbon nanotube thermoelectric devices by direct printing: Toward wearable energy converters. Applied Physics Letters, 2021; 118 (17): 173901 DOI: 10.1063/5.0042349

Cite This Page:

American Institute of Physics. "Nontoxic, flexible energy converters could power wearable devices." ScienceDaily. ScienceDaily, 27 April 2021. <www.sciencedaily.com/releases/2021/04/210427110648.htm>.
American Institute of Physics. (2021, April 27). Nontoxic, flexible energy converters could power wearable devices. ScienceDaily. Retrieved November 20, 2024 from www.sciencedaily.com/releases/2021/04/210427110648.htm
American Institute of Physics. "Nontoxic, flexible energy converters could power wearable devices." ScienceDaily. www.sciencedaily.com/releases/2021/04/210427110648.htm (accessed November 20, 2024).

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