Nanotube Water Doesn't Freeze

X-Message-Number: 26301
From: "Basie" <>
Subject: Nanotube Water Doesn't Freeze 
Date: Tue, 7 Jun 2005 17:35:15 -0400

Nanotube Water Doesn't Freeze -- Even At Hundreds Of Degrees Below Zero
ARGONNE, Ill. (May 13, 2005) -- A new form of water has been discovered by 
physicists in Argonne's Intense Pulsed Neutron Source (IPNS) Division. 
Called nanotube water, these molecules contain two hydrogen atoms and one 
oxygen atom but do not turn into ice -- even at temperatures near absolute 
zero.



New form of water in a nanotube. Water behaves differently when confined 
inside a long, narrow nanotube. The copper-colored exterior rings represent 
the carbon nanotube 1.4 nanometers across. The red and white interior 
cylinder is an icy wall with permanent hydrogen bonds shown in red; white 
represents oxygen. The interior chain is in constant motion. Yellow 
represents the hydrogen in the chain. Image by Christian J. Burnham, 
University of Houston.


Instead, inside a single wall tube of carbon atoms less than 2 nanometers, 
or 2 billionths of a meter wide, the water forms an icy, inner wall of water 
molecules with a chain of liquid-like water molecules flowing through the 
center. This occurs at 8 Kelvins, which is minus 445 Fahrenheit. As the 
temperature rises closer to room temperature, the nanotube water gradually 
becomes liquid.

Researchers ranging from biologists to geologists and materials scientists 
are interested in water's behavior in tightly confined spaces controlled by 
hydrophobic -- water repulsing -- materials because this situation is found 
in nature, for example when tiny roots carry water to plants. Some membrane 
proteins also face this challenge, including aquaporin, which controls water 
flow through cell walls.

This IPNS study is the first experiment with water in a nanotube. "I was 
surprised," said principal investigator Alexander Kolesnikov, "that no one 
has tried testing water in nanotubes. There have been a large number of 
calculations, made even more difficult because water is so difficult to 
model, but no experimental work."

"Even though people have been modeling water for decades," said visiting 
scientist Christian J. Burnham from the University of Houston, "we are only 
now just beginning to appreciate the importance of including the correct 
quantum-level description of the motion of the hydrogen nuclei and we are 
still working on a more accurate mathematical description of the charge 
clouds enveloping each water molecule."

Researchers Kolesnikov, Chun Loong, Nicolas de Souza, Pappannan Thiyagarajan 
and Jean-Marc Zanotti used the IPNS for the experiments. Instruments at the 
IPNS study atomic arrangements and motions in liquids and solids. The IPNS 
is open to researchers from industry, academia and other national and 
international laboratories.

Research partners at MER Corp., Tucson, Ariz., supplied the nanotube samples 
made of nearly pure carbon only one atom thick. Each tube was 1.4 nanometers 
across and 10,000 nanometers long; imagine a piece of dry, hollow spaghetti 
200 meters long because the nanotube is more than 7,000 times longer than 
wide.

"With this one-dimensional confinement," Kolesnikov said, "we expected 
something new, but not the characteristics we observed. Something 
extraordinary appeared."

What appeared was "totally different from bulk liquid or ice," said 
Kolesnikov. At 8 K, four-coordinated water molecules create an icy lining 
inside the naturally hydrophobic carbon nanotube. The lining free-floats 
inside the carbon nanotube with a 0.32 nanometer space all around it because 
that is as close as nature allows the water to the carbon. "An interior 
chain is running inside the lining, but compared to bulk water is much more 
mobile," Kolesnikov said.

Researchers attribute the peculiarities to the low "coordination numbers" of 
the molecules. In liquid water, an average of 3.8 (the coordination number) 
hydrogen bonds connect the molecule to its closest neighbors. In ice, four 
hydrogen bonds connect to its closest neighbors. In nanotube water, the 
number of hydrogen bonds for the chain water molecules is only 1.86.

"Because of the loose bonding, the water is very active and is always 
moving," Kolesnikov said. The icy lining is much more stable, but the mobile 
chain makes and breaks bonds continuously between parts of the chain and 
sometimes with the icy wall. A molecular divining rod

To prepare for the experiment, the carbon nanotube sample was exposed to 
water vapor for several hours and dried to remove exterior water. Then 
researchers studied it with several neutron scattering techniques at the 
IPNS. Neutrons are uncharged particles found in nearly all matter. When the 
IPNS sends beams of neutrons through materials, they reveal a material's 
structural and dynamic properties.

First, researchers used the Small Angle Neutron Diffractometer to determine 
that water filled only the interior of the nanotube. If water were on the 
exterior, it would have skewed the neutron-scattering results. Other neutron 
diffraction techniques provided the atomic arrangement, and inelastic and 
quasielastic neutron scattering measurements revealed the water's molecular 
motions.

Next, Burnham, an expert in modeling the molecular dynamics of water, 
developed the simulation that shows how the new form of water behaves in the 
nanotube.

The small scale of the materials was an advantage in creating the 
simulation, making it much faster in comparison to the simulation of, for 
instance, a biological structure thousands of times larger and more complex.

Another advantage, according to Kolesnikov, is that scientists from other 
disciplines will be able to isolate water's behavior in this one-dimensional 
confinement. "In the inelastic neutron scattering experiment, the carbon is 
almost invisible compared to the hydrogen atoms, so you only see the water. 
Biologists can use our information to understand how the water behaves in 
their much larger, complex models," Kolesnikov said.

Funding for this research was supplied by the U.S. Department of Energy's 
Office of Basic Energy Sciences.

Research continues. Burnham will expand his classical molecular dynamics 
research to include quantum effects using parallel computing with funding 
from Argonne's Theory Institute. IPNS researchers plan to look at water in 
nanotubes with smaller diameters close in size to membrane proteins that 
selectively transport water. They also want to study the thermodynamic 
properties of nanotube water.

Kolesnikov said he has studyied water on and off during his career "because 
it is so critical to everyday life -- here on Earth and in the planetary 
system."

This research was published in Physical Review Letters, July 16, 2004.

Editor's Note: The original news release can be found here.


Basie
http://www.agingtheory.com/pages/1/index.htm

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