Space Elevator Group to Open Nanotube Factory

FleaPlus writes "The Seattle Post-Intelligencer and Universe Today report that the LiftPort Group, a consortium dedicated to commercially developing and constructing a space elevator, will be opening a carbon nanotube manufacturing plant in June of this year. The new facility has been dubbed LiftPort Nanotech. Many expect the LiftPort Group to be a front-runner in NASA's recently-announced Centennial Challenges competitions for space elevator technologies, which begin in September of this year."

Linking to a 2.7MB PDF

Nice going, pointing to a 2.7MB PDF file. For those of you who want more information about the space elevator concept, visit the Wikipedia page on space elevators.

Not 100,000s of kilomters each, just fibres

From the faq http://www.liftport.com/faq.php

We don't need and are not counting on individual carbon nanotube molecules running the entire length of the space elevator or any significant fraction thereof. The individual fibers in a string or rope are only a few millimeters long, yet the rope has a large fraction of the theoretical strength of the fibers. This is even more the case with MOLECULES, several orders of magnitude smaller than a fiber. A diamond is said to be the "hardest substance in the world" because of the strength of the carbon bonds that make it up, but a diamond is not a single molecule. Likewise an SE could be made with CNTs just a few centimeters or millimeters long. (In fact, a CNT several centimeters long is a wonder; they're single molecules!)

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Japan's Mitsui built first nanotube factory

[FleaPlus]

After submitting the article a few days ago, it's come to my attention that this isn't going to be the first nanotube factory; I didn't explicitly say anything of the sort in the submission, but wanted to clear any possible assumptions. From an industry report:

Among the small wonders produced by nanotechnology are carbon nanotubes, an advanced material as strong as diamond. These amazing carbon cylinders possess 100 times the tensile strength of steel and are 10,000 times finer than human hair. They are believed to conduct heat better than any other material, and they can also conduct electricity or function as semiconductors.

"Nanotubes are astonishingly promising, and I'm a realist, not an optimist," says Rod Ruoff, a mechanical engineering professor at Northwestern University. "It's a question of making the technology cheap enough." In 2001, only 3 kilograms of the highest quality carbon nanotubes--the single-walled variety--were produced worldwide, each gram worth $300, or 30 times as expensive as gold.

Now, full-scale production of carbon nanotubes is underway at the world's first ever large-scale nanotube factory, built outside Tokyo by the Carbon Nanotech Research Institute, a subsidiary of Japan's Mitsui & Co. The new facility is expected to churn out 10 tons of carbon nanotubes--albeit the lesser quality multi-walled type--a month, and CNRI anticipates the price will be a much more reasonable $80 a kilogram.

These multi-walled carbon nanotubes may not possess all the impressive properties of their single-walled brethren, but mixed with plastics, they make ultrastrong composites or microscale precision parts. Such carbon nanotube-filled plastics are already being used by automakers in fuel lines because they are conductive and can thus be grounded to release static electricity, which can ignite flammable gasoline.