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The
science-fiction fantasy of nanotechnology — building
novel structures, devices, and materials at the atomic
or molecular scale — is becoming a reality. For the
great potential of nanoscience and nanotechnology to be
fully realized, however, research efforts must cross many
disciplines, from electrical engineering, mechanical engineering,
materials science, and computer science to bioengineering,
chemistry, and physics.
Nowhere
is this cross-disciplinary approach fostered more than
at UC Berkeley. Each month, Lab Notes is proud
to present the work of nanotechnology researchers from
the College of Engineering and our collaborators across
the campus.
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The Tinkertoys
of Nanotechnology
by David Pescovitz
Alexander
Zettl holds a model of a carbon nanotube, the molecular
basis for his nanoscale devices.
Courtesy
Lawrence Berkeley National Laboratory
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Alex Zettl is an expert builder with the tinkertoys of nanotechnology,
carbon nanotubes. By altering the properties and formation of these
rolled-up crystalline sheets of atoms, the UC Berkeley physicist
has forged some of the world's smallest bearings, switches, diodes,
and sensors.
"The most exciting thing is that a lot of structures we are
now making in the laboratory and studying are very relevant to everyday
life, from being used as structural materials, to electronic materials,
to chemical sensing," says Zettl, who is also a researcher
in the Materials Science Division of Lawrence Berkeley National
Laboratory (LBNL). "In almost any technological application
you want to think of, nanotubes probably will have an impact."
Discovered by a Japanese scientist in 1991, nanotubes form naturally
during the vaporization of carbon rods. Resembling a roll of chicken
wire fused at the seam, the tubes of carbon atoms are less than
two nanometers in diameter and can be stretched to lengths of several
thousand nanometers. The real magic is in the properties: they're
excellent conductors of heat and electricity and are about ten times
stronger than steel at one-sixth the weight.
The
outer radius of the telescoping multi-walled carbon nanotube
seen in this transmission electron microscope image is only
12.6 nanometers at its largest point, nearly 10,000 times
thinner than a human hair.
Courtesy
Lawrence Berkeley National Laboratory
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One of the biggest potential payoff for nanotubes will likely be
in the arena of molecular electronics. Scientists predict that within
ten years, silicon scaling will hit its physical limits. In the
post-silicon age, carbon nanotubes may help realize the science
fiction dream of supercomputers the size of sugarcubes.
Research
toward this distant goal is still in its infancy, but Zettl and
his colleagues have made significant strides. Previous work at LBNL
showed that depending upon geometry or diameter, single-walled carbon
nanotubes can either be metallic or semiconducting, key properties
when constructing electronic components. By precisely depositing
tubes with dissimilar properties in a crossed formation, Zettl and
his collaborators built a nanoscale transistor, the basic building
block of computer circuits.
Rather than building
nanoscale circuits one component at a time, Zettl hopes someday
to build a "tube cube" randomly packed with billions of
nanotubes that form a jumbled network of electronic components.
The cube, he says, could potentially configure itself to perform
desired tasks.
Computer
graphics, like this one of a multi-walled carbon nanotube
telescopic extension, enable nanotechnology researchers
to simulate the properties of the structures they create.
(Click for larger image.)
Courtesy
Lawrence Berkeley National Laboratory
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In the nearer term, Zettl's nanotubes will help advance the functionalities
of micro-electromechanical systems (MEMS), tiny devices mass-produced
in a process similar to the way integrated circuits are fabricated.
One major engineering challenge faced by MEMS researchers is the
frictional wear that occurs when their tiny contraptions — pistons
and bearings, for example — actuate thousands of times each second.
To solve the problem, Zettl devised a system of telescoping nanotubes
that slide in and out like a car antenna. Because all of the bonds
of the carbon molecules that make up a nanotube are satisfied, there
is literally no friction when the shaft moves within its sleeve.
In addition to functioning as a piston or bearing, Zettl has shown
that nested nanotubes could also act as electromechanical switches.
When an inner tube is extended, he explains, it could bridge the
gap between two metals to close a circuit. When triggered though,
the telescoped tube could snap back into its sheath in less than
ten billionths of a second, almost instantly breaking the circuit.
Last year, Zettl and UC Berkeley collaborator Marvin Cohen founded
Nanomix (formerly Covalent Materials), a company dedicated to commercializing
nanotube technology. The firm's first product will likely be nanotube-based
sensors for biochemical diagnostics, medical monitoring, and the
detection of toxic gas leaks and other chemical and environmental
hazards. A nanotube's conductivity, Zettl explains, changes when
a specific particle binds to it, not unlike barnacles glomming on
to the hull of a ship. By measuring the variance in conductivity,
the device will be able to identify a specific particle in the sample.
According to Zettl, an array of nanotubes integrated onto tiny Smart
Dust sensors could enable the detection of trace levels of many
molecules much more cheaply and efficiently than current technologies
like mass spectroscopy.
"With nanotubes, we're not seeing the beginning of something
that might lead to something 25 years down the road," Zettl
says. "These are things that are crying out to be exploited
in the near future. Nanotubes are on a venture-capital timescale."
Zettl Research Group
Nanomix
Lab Notes is published online by the Public Affairs Office of the UC Berkeley College of Engineering. The Lab Notes mission is to illuminate groundbreaking
research underway today at the College of Engineering that will dramatically change our lives tomorrow.
Editor, Director of Public Affairs: Teresa Moore
Writer, Researcher: David Pescovitz
Designer: Robyn Altman
Subscribe or send comments to the Engineering Public Affairs Office: lab-notes@coe.berkeley.edu.
© 2002 UC Regents.
Updated 6/20/02.
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