Sanding powder into a material provides the right properties for superhydrophobicity
From: Rice University
August 4, 2022 -- Scientists
and engineers have developed a one-step method involving sandpaper and powder
to make robust superhydrophobic materials.
Rice University
researchers have developed a simple method to make surfaces superhydrophobic --
that is, very water-repellant -- without the chemicals often used in such
processes.
Their technique
involves sandpaper, a selection of powders and some elbow grease.
The labs of Rice
professors C. Fred Higgs III and James Tour, co-corresponding authors of a
paper in the American Chemical Society journal ACS Applied Materials and
Interfaces, showed that sanding a surface increases its ability to shed water
without getting wet. But grinding in a powder at the same time gives it
hydrophobic superpowers.
Better yet, their
superhydrophobic surfaces also have excellent anti-icing properties. They found
it took water 2.6 times longer to freeze on treated surfaces compared to
untreated materials. They also noticed that ice lost 40% of its adhesion
strength, even in temperatures as low as minus 31 degrees Fahrenheit.
How well a surface
absorbs or repels water can be measured by analyzing the contact angle of
droplets that settle there. To be superhydrophobic, a material has to have a
water contact angle -- the angle at which the surface of the water meets the
surface of the material -- larger than 150 degrees. The greater the beading,
the higher the angle. An angle of zero degrees is a puddle, while a maximum
angle of 180 degrees is a sphere that just touches the surface.
To achieve their super
status, hydrophobic materials have low surface energy as well as a rough
surface. The Rice team's best materials showed a contact angle of about 164
degrees.
Higgs, whose lab
specializes in tribology, the study of surfaces in sliding contact, said certain
types of sandpaper can provide surface roughness that promotes the desired
water-repelling or hydrophobic behavior.
"However, the Tour
group's idea of introducing select powder materials between the rubbing
surfaces during the sand-in process means a tribofilm is formed," Higgs
said. "That gives the added bonus of functionalizing the surface to repel
water ever more."
A tribofilm forms in a
chemical reaction on surfaces sliding against each other. The surface of an
engine's piston is a good example, he said.
Higgs said sanding
roughens softer surfaces and allows the powders to adhere through van der Waals
forces. "These forces are at their greatest when surfaces come into close
contact," he said. "Therefore, powder particles can adhere even after
the sand-in process is completed."
Structural changes and
mass and electron transfer appear to lower the surface energy of the materials
that, before treatment, were already either mildly hydrophobic or hydrophilic,
according to the researchers.
The Rice team applied
the technique on a variety of surfaces (Teflon, polyethylene, polypropylene,
polystyrene, polyvinyl chloride and polydimethylsiloxane) with a variety of
powder additives. These included laser-induced graphene fiber, turbostratic
flash graphene, molybdenum disulfide, Teflon and boron nitride. A variety of
aluminum oxide sandpapers were used, from 180- to 2,000-grit.
The resistant materials
proved to be robust, as neither heating to 130 degrees Celsius (266 degrees
Fahrenheit) nor 18 months under the hot Houston sun degraded them. Sticking
transparent tape to the surface and peeling it off 100 times did not degrade
them, either. But even when the materials began to fail, the labs found that
re-sanding them could easily refresh their hydrophobicity.
The team also
discovered that by changing the sand-in conditions and the powder additives,
materials can also be made hydrophilic, or water-absorbing.
Tour said simplifying
the manufacture of superhydrophobic and anti-icing materials should draw
industry interest. "It's hard to make these materials," he said.
"Superhydrophobic surfaces do not permit water accumulation. The water
beads and rolls right off if there is even the slightest angle or gentle wind.
"Now, almost any
surface can be made superhydrophobic in seconds," Tour said. "The
powders can be as simple as Teflon or molybdenum disulfide, both of which are
readily available, or newer graphene materials. Many industries could take
advantage of this, from builders of aircraft and boats to skyscrapers, where low-ice
adhesion is essential."
"Airplane
manufacturers do not want ice forming on their wings, ship captains do not want
drag from ocean water slowing them down and biomedical devices need to avoid
biofouling, where bacteria builds up on wet surfaces," Higgs said.
"Robust, long-lasting superhydrophobic surfaces produced from this
one-step, sand-in method can alleviate many of these problems.
"A limitation of
other techniques to generate hydrophobic surfaces is that they do not scale up
to large surface areas such as those on planes and ships," he said.
"Simple application techniques like the one developed here should be
scalable."
Rice graduate student
Weiyin Chen, co-lead author of the new paper, said the Tour lab has also
applied its sand-in technique to various metal surfaces including, as reported
in another recent paper, lithium and sodium foils for metal batteries.
"The spontaneous
chemical reactions cause the formation of tribofilms, in this case, the
artificial solid electrolyte interphase," Chen said. "The modified
metals can be used as the anodes for rechargeable metal batteries."
https://www.sciencedaily.com/releases/2022/08/220804130650.htm
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