Sandia National Laboratories has come up with an inexpensive way to
synthesize titanium-dioxide nanoparticles and is seeking partners who
can demonstrate the process at industrial scale for everything from
solar cells to light-emitting diodes (LEDs).
Titanium-dioxide (TiO2) nanoparticles show great promise as
fillers to tune the refractive index of anti-reflective coatings on
signs and optical encapsulants for LEDs, solar cells and other optical
devices. Optical encapsulants are coverings or coatings, usually made of
silicone, that protect a device.
Industry has largely shunned TiO2 nanoparticles because they’ve been difficult and expensive to make, and current methods produce particles that are too large.
Sandia became interested in TiO2 for optical encapsulants because of its work on LED materials for solid-state lighting.
Current production methods for TiO2 often require
high-temperature processing or costly surfactants — molecules that bind
to something to make it soluble in another material, like dish soap does
with fat.
Those methods produce less-than-ideal nanoparticles that are very
expensive, can vary widely in size and show significant particle
clumping, called agglomeration.
Sandia’s technique, on the other hand, uses readily available,
low-cost materials and results in nanoparticles that are small, roughly
uniform in size and don’t clump.
“We wanted something that was low cost and scalable, an
d that made
particles that were very small,” said researcher Todd Monson, who along
with principal investigator Dale Huber patented the process in mid-2011
as “High-yield synthesis of brookite TiO2 nanoparticles.”
Low-cost technique produces uniform nanoparticles that don’t clump
Their method produces nanoparticles roughly 5 nanometers in diameter,
approximately 100 times smaller than the wavelength of visible light,
so there’s little light scattering, Monson said.
“That’s the advantage of nanoparticles — not just nanoparticles, but small nanoparticles,” he said.
Scattering decreases the amount of light transmission. Less
scattering also can help extract more light, in the case of an LED, or
capture more light, in the case of a solar cell.
TiO2 can increase the refractive index of materials, such
as silicone in lenses or optical encapsulants. Refractive index is the
ability of material to bend light. Eyeglass lenses, for example, have a
high refractive index.
Practical nanoparticles must be able to handle different surfactants
so they’re soluble in a wide range of solvents. Different applications
require different solvents for processing.
Technique can be used with different solvents
“If someone wants to use TiO2 nanoparticles in a range of
different polymers and applications, it’s convenient to have your
particles be suspension-stable in a wide range of solvents as well,”
Monson said. “Some biological applications may require stability in
aqueous-based solvents, so it could be very useful to have surfactants
available that can make the particles stable in water.”
The researchers came up with their synthesis technique by pooling
their backgrounds — Huber’s expertise in nanoparticle synthesis and
polymer chemistry and Monson’s knowledge of materials physics. The work
was done under a Laboratory Directed Research and Development project Huber began in 2005.
“The original project goals were to investigate the basic science of
nanoparticle dispersions, but when this synthesis was developed near the
end of the project, the commercial applications were obvious,” Huber
said. The researchers subsequently refined the process to make particles
easier to manufacture.
Existing synthesis methods for TiO2 particles were too
costly and difficult to scale up production. In addition, chemical
suppliers ship titanium-dioxide nanoparticles dried and without
surfactants, so particles clump together and are impossible to break up.
“Then you no longer have the properties you want,” Monson said.
The researchers tried various types of alcohol as an inexpensive
solvent to see if they could get a common titanium source, titanium
isopropoxide, to react with water and alcohol.
The biggest challenge, Monson said, was figuring out how to control
the reaction, since adding water to titanium isopropoxide most often
results in a fast reaction that produces large chunks of TiO2,
rather than nanoparticles. “So the trick was to control the reaction by
controlling the addition of water to that reaction,” he said.
Textbooks said making nanoparticles couldn’t be done, Sandia persisted
Some textbooks dismissed the titanium isopropoxide-water-alcohol method as a way of making TiO2 nanoparticles.
Huber and Monson, however, persisted until they discovered how to add
water very slowly by putting it into a dilute solution of alcohol. “As
we tweaked the synthesis conditions, we were able to synthesize
nanoparticles,” Monson said.
The next step is to demonstrate synthesis at an industrial scale,
which will require a commercial partner. Monson, who presented the work
at Sandia’s fall Science and Technology Showcase, said Sandia has received inquiries from companies interested in commercializing the technology.
“Here at Sandia we’re not set up to produce the particles on a
commercial scale,” he said. “We want them to pick it up and run with it
and start producing these on a wide enough scale to sell to the end
user.”
Sandia would synthesize a small number of particles, then work with a
partner company to form composites and evaluate them to see if they can
be used as better encapsulants for LEDs, flexible high-index refraction
composites for lenses or solar concentrators. “I think it can meet
quite a few needs,” Monson said.
source:
Sandia news media contact: Sue Holmes, sholmes@sandia.gov, (505) 844-6362
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