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February 11, 2004
A: FROM MENTOR LEE
PELLEGRINO-GENSEY IN NJ
Here's a web site explaining the concept of space elevators
and Legrange
points:
http://www.airspacemag.com/ASM/Mag/Index/2004/DJ/100Y.html
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A: FROM MENTOR JOAN LUSK IN
RI
I'm not sure I believe this, but there are people who think
it can be done. Nanotechnology in general and making nanotubes
is clearly a very active research area nowadays, so the necessary
stong materials may be feasible. It's still hard for me to
believe that the top of the cable could be in orbit like a
satellite and support the rest of the cable, though - maybe
it is just "simple physics." Here's a site and a
long quote from it:
http://www.space.com/businesstechnology/technology/space_elevator_020327-1.html
For a space elevator to function, a cable with one end attached
to the Earth's surface stretches upwards, reaching beyond
geosynchronous orbit, at 21,700 miles (35,000-kilometer altitude).
After that, simple physics takes charge.
The competing forces of gravity at the lower end and outward
centripetal acceleration at the farther end keep the cable
under tension. The cable remains stationary over a single
position on Earth. This cable, once in position, can be scaled
from Earth by mechanical means, right into Earth orbit. An
object released at the cable's far end would have sufficient
energy to escape from the gravity tug of our home planet and
travel to neighboring the moon or to more distant interplanetary
targets.
Putting physics aside the toughest challenge has been finding
a super-strong cable material. "That's what has kept
this idea in science fiction for 40 years," Edwards said.
But the right stuff in terms of cable material is no longer
thought of as "unobtainium", he said.
The answer is carbon-nanotube-composite ribbon. Small fibers
of the material are set down side-by-side, then interconnected
to form a growing ribbon.
Stronger than steel
The hurdle to date, Edwards said, has been the commercial
fabrication of carbon nanotubes. Both U.S. and Japanese firms,
among others, are ramping up production of carbon nanotubes,
with tons of this now exotic matter soon to be available.
"That quantity of material is going to be around well
before five years time. It's not going to take long,"
he said.
Given the far stronger-than-steel ribbon of carbon nanotubes,
a space elevator could be up within a decade. "There's
no real serious stumbling block to this," Edwards explained.
"The making of carbon nanotubes is moving very quick,"
said Hayam Benaroya, a professor in the Department of Mechanical
and Aerospace Engineering at Rutgers in Piscataway, New Jersey.
"We're moving from the scientific stage of just developing
them to actual commercial entities producing them in ton-like
quantities," he said.
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