are mimicking transport across cellular membranes with manmade carbon nanotube
membranes that are 100,000 times smaller than a human hair.
Artist's rendering of methane molecules flowing through a carbon nanotube less than 2 nanometers in diameter. (Image by Scott Dougherty, LLNL.)
Molecular transport across cellular
membranes is essential to many of life’s processes, including electrical
signaling in nerves, muscles and synapses. In biological systems, the membranes
often contain a slippery inner surface with selective filter regions made up of
specialized protein channels of sub-nanometer size. These pores regulate
cellular traffic, allowing some of the smallest molecules in the world to
traverse the membrane extremely quickly while at the same time rejecting other
small molecules and ions.
Researchers at Lawrence Livermore National Laboratory (LLNL) are mimicking that
process with manmade carbon nanotube membranes, which have pores that are
100,000 times smaller than a human hair, and were also able to determine the
rejection mechanism within the pores. “Hydrophobic, narrow-diameter carbon
nanotubes can provide a simplified model of membrane channels by reproducing
these critical features in a simpler and more robust platform,” said Olgica
Bakajin, who led the LLNL team whose study appeared in the June 6 online edition
of the journal Proceedings of the National
Academy of Sciences.
In the initial discovery, reported in the
May 19, 2006, issue of the journal Science, the LLNL team found that water molecules in
a carbon nanotube move fast and do not stick to the nanotube’s super-smooth
surface, much like water moves through biological channels. The water molecules
travel in chains because they interact with each other strongly via hydrogen
“You can visualize it as mini-freight trains of chain-bonded water molecules
flying at high speed through a narrow nanotube tunnel,” said Hyung Gyu Park, an LLNL postdoctoral researcher
and a team member.
The animation starts with the depiction of the water flow through a regular "rough" pipe. The molecules near the wall stick to it and move much slower than the molecules in the middle of the pipe. Colors indicate the speed of the molecules (green are fast, yellow are slower, red are the slowest). The rough pipe fades and the carbon nanotube appears. All the molecules in the carbon nanotube move fast (green). They do not stick to the surface of the nanotube because that surface is very slippery. The water molecules travel in chains because they interact with each other strongly via hydrogen bonds. These two effects (the slippery nanotube surface and formation of water molecule chains inside the nanotube) combine to produce this phenomenon of ultra-fast flow through carbon nanotubes. (Animation by Kwei-Yu Chu/LLNL.)
In the recent study, the researchers wanted to find out if the membranes with 1.6 nanometer (nm) pores reject ions that make up common salts. In fact, the pores did reject the ions and the team was able to understand the rejection mechanism. “Our study showed that in pores with a diameter of 1.6 nm on the average, the salts get rejected due to the charge at the ends of the carbon nanotubes,” said Francesco Fornasiero, an LLNL postdoctoral researcher, team member and the study’s first author.
Fast flow through carbon nanotube pores makes nanotube membranes more permeable than other membranes with the same pore sizes. Yet, just like conventional membranes, nanotube membranes exclude ions and other particles due to a combination of small pore size and pore charge effects.
“While carbon nanotube membranes can achieve similar rejections as membranes with similarly sized pores, they will provide considerably higher permeability, which makes them potentially much more efficient than the current generation of membranes,” said Aleksandr Noy, a senior member of the LLNL team.
Researchers will be able to build better membranes when they can independently change pore diameter, charge and material that fills gaps between carbon nanotubes. One of the most promising applications for carbon nanotube membranes is sea water desalination. These membranes will someday be able to replace conventional membranes and greatly reduce energy use for desalination.
Founded in 1952, Lawrence Livermore National Laboratory has a mission to ensure national security and to apply science and technology to the important issues of our time. LLNL is managed by Lawrence Livermore National Security, LLC, for the U.S. Department of Energy’s National Nuclear Security Administration. For additional information, visit www.llnl.gov.