Thermal

Multiwalled Carbon Nanotube Yarn

Multiwalled Carbon Nanotube Yarn
This scanning electron microscope image shows nanotube yarn fibers drawn from a "nanotube forest." Nanometer and micron-sized yarn or fibers drawn from multiwalled carbon nanotubes can have tensile strengths comparable to or exceeding those of spider silk. Replacing metal wires in electronic textiles with these nanotube yarns could lead to important new functionalities, such as the ability to actuate (as an artificial muscle) and to store energy (as a fiber super-capacitor or battery).

Minimum credit: 

Mei Zhang, UTD

Size: 

The yarn's diameter is about 1 µm. The nanotubes from which it is being drawn are each about 10 nm in diameter.

Pixels: Width: 

1017

Pixels: Height: 

713

Permissions:

This image was created by another institution, not the NISE Network. This image is available to NISE Network member organizations for non-profit educational use only. Uses may include but are not limited to reproduction and distribution of copies, creation of derivative works, and combination with other assets to create exhibitions, programs, publications, research, and Web sites. Minimum credit required.

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Silicon Nanowire Device

Silicon Nanowire Device
This scanning electron microscope image shows a silicon nanowire resting on two silicon nitride (SiNx) membranes. Thermoelectric materials convert heat to electricity and vice versa. Most fossil-fuel-powered engines generate waste heat, so researchers are using nanotechnologies to explore ways of making thermoelectric devices more efficient in order to convert that waste heat to usable power—and thus save energy. This assembly was built to measure the thermal conductivity of a silicon nanowire synthesized specifically for thermoelectric applications.

Minimum credit: 

Renkun Chen, University of California at Berkeley

Size: 

The diameter of the central nanowire is approximately 100 nm.

Pixels: Width: 

510

Pixels: Height: 

441

Permissions:

This image was created by another institution, not the NISE Network. This image is available to NISE Network member organizations for non-profit educational use only. Uses may include but are not limited to reproduction and distribution of copies, creation of derivative works, and combination with other assets to create exhibitions, programs, publications, research, and Web sites. Minimum credit required.

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Silicon Nanowire

Silicon Nanowire
This transmission electron microscope image shows a single silicon nanowire. Thermoelectric materials convert heat to electricity and vice versa. Most fossil-fuel-powered engines generate waste heat, so researchers are using nanotechnologies to explore ways of making thermoelectric devices more efficient in order to convert that waste heat to usable power—and thus save energy.

Minimum credit: 

Renkun Chen, University of California at Berkeley

Size: 

The diameter of this nanowire is approximately 100 nm.

Pixels: Width: 

1215

Pixels: Height: 

1215

Permissions:

This image was created by another institution, not the NISE Network. This image is available to NISE Network member organizations for non-profit educational use only. Uses may include but are not limited to reproduction and distribution of copies, creation of derivative works, and combination with other assets to create exhibitions, programs, publications, research, and Web sites. Minimum credit required.

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Silicon Nanowire Array

Silicon Nanowire Array
This is a scanning electron microscope image of a silicon nanowire array synthesized for thermoelectric applications. Thermoelectric materials convert heat to electricity and vice versa. Most fossil-fuel-powered engines generate waste heat, so researchers are using nanotechnologies to explore ways of making thermoelectric devices more efficient in order to convert that waste heat to usable power—and thus save energy.

Minimum credit: 

Renkun Chen, University of California at Berkeley

Size: 

Each nanowire is approximately 100 nm in diameter.

Pixels: Width: 

1233

Pixels: Height: 

1233

Permissions:

This image was created by another institution, not the NISE Network. This image is available to NISE Network member organizations for non-profit educational use only. Uses may include but are not limited to reproduction and distribution of copies, creation of derivative works, and combination with other assets to create exhibitions, programs, publications, research, and Web sites. Minimum credit required.

Return to gallery