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Production and Characterization of Carbon Nanotubes and Nanotube-Based CompositesThe Nobel Prize winning discovery of the Buckuball (C60) in 1985 at Rice University by a group including Dr. Richard Smalley led to the whole new class of carbon allotropes including fullerenes and nanotubes. Especially interesting from many viewpoints are single-walled carbon nanotubes, which structurally are like a single graphitic sheet wrapped around a cylinder and capped at the ends. This cylinders have diameter as small as 0.5 - 2 nm (1/100,000th the diameter of a human hair) and are as long as 0.1 - 1 mm. Nanotubes are really individual molecules and believed to be defect-free, leading to high tensile strength despite their low density. Additionally, these fibers exhibit electrical conductivity as high as copper, thermal conductivity as high as diamond, strength 100 times higher than steel at one-sixth the weight, and high strain to failure. Thus it is believed that developments in the field of nanotechnology will lead to stronger and lighter composite materials for next generation spacecraft. Lack of a bulk method of production is the primary reason nanotubes are not used widely today. Toward this goal JSC nanotube team is exploring three distinct production techniques: laser ablation, arc discharge and chemical vapor deposition (CVD, in collaboration with Rice University). In laser ablation technique high-power laser impinges on the piece of carbon containing small amount of catalyst, and nanotubes self-assemble from the resulting carbon vapor. In arc generator similar vapor is created in arc discharge between carbon electrodes with catalyst. In CVD method nanotubes grow at much lower temperature on small catalyst particles from carbon-containing feedstock gas (methane or carbon monoxide). As of now, laser ablation produces cleanest material, but mass yield is rather small. Arc discharge produces grams of material, but purity is low. CVD technique is still in baby steps, but preliminary results look promising, as well as perspective of scaling the process up. We are also working on necessary purification of nanotubes. Applications of nanotubes are in such various fields as lightweight composites, molecular electronics, energy storage (electrodes in Li ion batteries), flat panel displays, conductive polymers, etc. JSC nanotube team is focused on development of lightweight materials. We work on the injection thermoset epoxies reinforced with nanotubes. Early results show good wetting of nanotube surface with epoxy, which is very important. More research will be possible as more nanotubes become available.
Document ID
20000111073
Acquisition Source
Johnson Space Center
Document Type
Preprint (Draft being sent to journal)
Authors
Nikolaev, Pavel
(Lockheed Martin Corp. Houston, TX United States)
Arepalli, Sivaram
(Lockheed Martin Corp. Houston, TX United States)
Holmes, William
(Lockheed Martin Corp. Houston, TX United States)
Gorelik, Olga
(Lockheed Martin Corp. Houston, TX United States)
Files, Brad
(NASA Johnson Space Center Houston, TX United States)
Scott, Carl
(NASA Johnson Space Center Houston, TX United States)
Santos, Beatrice
(NASA Johnson Space Center Houston, TX United States)
Mayeaux, Brian
(NASA Johnson Space Center Houston, TX United States)
Victor, Joe
(NASA Johnson Space Center Houston, TX United States)
Date Acquired
August 19, 2013
Publication Date
January 1, 1999
Subject Category
Composite Materials
Meeting Information
Meeting: Developing Space Operations, Technology, and Utilization
Location: Houston, TX
Country: United States
Start Date: May 28, 1999
Sponsors: American Inst. of Aeronautics and Astronautics
Distribution Limits
Public
Copyright
Work of the US Gov. Public Use Permitted.

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