Jumbo ‘nanotube’ existence confirmed at Sandia/LANL nanotech center

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Neal Singer
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505-845-7078

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JUMBO TUBES -- a scanning electron microscope image (left) of a huge carbon tube. Images at right depict cross-sectional view of the tube, with rectangular pore tunnels visible in its wall.<br />
(Media are welcome to download/publish this image with related news stories.)

Jumbo Nanotube

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JUMBO TUBES -- a scanning electron microscope image (left) of a huge carbon tube. Images at right depict cross-sectional view of the tube, with rectangular pore tunnels visible in its wall.
(Media are welcome to download/publish this image with related news stories.)

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photo by Sandi/LANL Center for Integrated Nanotechnologies

JUMBO TUBES -- a scanning electron microscope image (left) of a huge carbon tube. Images at right depict cross-sectional view of the tube, with rectangular pore tunnels visible in its wall. (photo by Sandi/LANL Center for Integrated Nanotechnologies)
JUMBO TUBES — a scanning electron microscope image (left) of a huge carbon tube. Images at right depict cross-sectional view of the tube, with rectangular pore tunnels visible in its wall. (photo by Sandi/LANL Center for Integrated Nanotechnologies)

ALBUQUERQUE, N.M. — A jumbo nanotube, like a jumbo shrimp, sounds contradictory.

A giant lightweight carbon nanotube with good strength and electrical properties is desirable, all right. A micron-sized carbon tube is easier to exploit commercially than any (so to speak) littler nanocousin.

But is it still a nanotube?

Jianyu Huang at the joint Sandia and Los Alamos national laboratories Center for Integrated Nanotechnologies (CINT), with colleagues elsewhere, got around this problem by naming their new creation “colossal carbon tubes” in a paper published in a recent issue of Physical Review Letters.

“The structures are remarkable because they are very light, possess good electrical conductivity, and mechanical properties similar to carbon fibers,” Huang says.

Among possibilities of use are so-called textile electronics and body armor.

Because of their strange, surprising sponginess — walls of graphite-like carbon kept apart by hollow, rectangular compartments — the colossal fibrous tubes are 20 times less dense than carbon fibers, yet about the same length — in the centimeter range. And they appear to be slightly stronger — a very desirable, and until now unheard-of property in large carbon tubes.

The new form of carbon surprised leading nanotechnology researchers. MIT’s carbon technology specialist Mildred Dresselhaus was quoted in an online news article in the journal Nature: “This is a new form of carbon that was unexpected to me.”

Huang, who did the microstructure analysis confirming that the walls of such tubes consist of graphitic structure, describes the new creation as “a porous, giant, carbon fiber-like tubular structure” of diameters ranging from 40 to 100 microns. Conventional carbon nanotubes are about 10 nanometer diameter.

The material was made at Los Alamos National Laboratory. Researchers there led by Yuntian Zhu and Huisheng Peng found that heating ethylene and paraffin oil produced a carbon vapor that condensed into tubes of pure carbon tens of microns wide and up to several centimeters long. Zhu now is at North Carolina State University, and Huisheng Peng is at Tongji University in Shanghai.

 

Sandia National Laboratories is a multimission laboratory operated by National Technology and Engineering Solutions of Sandia LLC, a wholly owned subsidiary of Honeywell International Inc., for the U.S. Department of Energy’s National Nuclear Security Administration. Sandia Labs has major research and development responsibilities in nuclear deterrence, global security, defense, energy technologies and economic competitiveness, with main facilities in Albuquerque, New Mexico, and Livermore, California.

Sandia news media contact

Neal Singer
nsinger@sandia.gov
505-845-7078