But at nanometer-size scales for water and potentially other fluids,
whether the container is made of glass or plastic does make a
significant difference. A new study shows that in nanoscopic channels,
the effective viscosity of water in channels made of glass can be twice
as high as water in plastic channels. Nanoscopic glass channels can make
water flow more like ketchup than ordinary H2O.
The effect of container properties on the fluids they hold offers yet
another example of surprising phenomena at the nanoscale. And it also
provides a new factor that the designers of tiny mechanical systems must
take into account.
"At the nanoscale, viscosity is no longer constant, so these results
help redefine our understanding of fluid flow at this scale," said Elisa
Riedo, an associate professor in the School of Physics at the Georgia
Institute of Technology. "Anyone performing an experiment, developing a
technology or attempting to understand a biological process that
involves water or another liquid at this size scale will now have to
take the properties of surfaces into account."
Those effects could be important to designers of devices such as high
resolution 3D printers that use nanoscale nozzles, nanofluidic systems
and even certain biomedical devices. Considering that nano-confined
water is ubiquitous in animal bodies, in rocks, and in nanotechnology,
this new understanding could have a broad impact.
Research into the properties of liquids confined by different
materials was sponsored by the Department of Energy's Office of Basic
Sciences and the National Science Foundation. The results were scheduled
to be reported September 19 in the journal Nature Communications.
The viscosity differences created by container materials are directly
affected by the degree to which the materials are either hydrophilic --
which means they attract water -- or hydrophobic -- which means they
repel it. The researchers believe that in hydrophilic materials, the
attraction for water -- a property known as "wettability" -- makes water
molecules more difficult to move, contributing to an increase in the
fluid's effective viscosity. On the other hand, water isn't as attracted
to hydrophobic materials, making the molecules easier to move and
producing lower viscosity.
In research reported in the journal, this water behavior appeared
only when water was confined to spaces of a few nanometers or less --
the equivalent of just a few layers of water molecules. The viscosity
continued to increase as the surfaces were moved closer together.
The research team studied water confined by five different surfaces:
mica, graphene oxide, silicon, diamond-like carbon, and graphite. Mica,
used in the drilling industry, was the most hydrophilic of the
materials, while graphite was the most hydrophobic.
"We saw a clear one-to-one relationship between the degree to which
the confining material was hydrophilic and the viscosity that we
measured," Riedo said.
Experimentally, the researchers began by preparing atomically-smooth
surfaces of the materials, then placing highly-purified water onto them.
Next, an AFM tip made of silicon was moved across the surfaces at
varying heights until it made contact. The tip -- about 40 nanometers in
diameter -- was then lifted up and the measurements continued.
As the viscosity of the water increased, the force needed to move the
AFM tip also increased, causing it to twist slightly on the cantilever
beam used to raise and lower the tip. Changes in this torsion angle were
measured by a laser bounced off the reflective cantilever, providing an
indication of changes in the force exerted on the tip, the viscous
resistance exerted -- and therefore the water's effective viscosity.
"When the AFM tip was about one nanometer away from the surface, we
began to see an increase of the viscous force acting on the tip for the
hydrophilic surfaces," Riedo said. "We had to use larger forces to move
the tip at this point, and the closer we got to the surface, the more
dramatic this became."
Those differences can be explained by understanding how water behaves differently on different surfaces.
"At the nanoscale, liquid-surface interaction forces become
important, particularly when the liquid molecules are confined in tiny
spaces," Riedo explained. "When the surfaces are hydrophilic, the water
sticks to the surface and does not want to move. On hydrophobic
surfaces, the water is slipping on the surfaces. With this study, not
only have we observed this nanoscale wetting-dependent viscosity, but we
have also been able to explain quantitatively the origin of the
observed changes and relate them to boundary slip. This new
understanding was able to explain previous unclear results of energy
dissipation during dynamic AFM studies in water."
While the researchers have so far only studied the effect of the
material properties in water channels, Riedo expects to perform similar
experiments on other fluids, including oils. Beyond simple fluids, she
hopes to study complex fluids composed of nanoparticles in suspension to
determine how the phenomenon changes with particle size and chemistry.
"There is no reason why this should not be true for other liquids,
which means that this could redefine the way that fluid dynamics is
understood at the nanoscale," she said. "Every technology and natural
process that uses liquids confined at the nanoscale will be affected."
In addition to Riedo, co-authors of the paper included Deborah
Ortiz-Young, Hsiang-Chih Chiu and Suenne Kim, who were at Georgia Tech
when the research was done, and Kislon Voitchovsky of the Ecole
Polytechnique Federale de Lausanne in Switzerland.
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