By David Szondy
The chemical tree got a bit of a shake this week with scientists at IBM
announcing the discovery of the first new class of polymer materials in
decades. Discovered using a combination of lab experiments and computer
modelling, the new plastics have properties that could potentially have
a huge impact in manufacturing, transportation, aerospace, and micro
electronics.
The chemical tree got a bit of a shake this week with scientists at IBM
announcing the discovery of the first new class of polymer materials in
decades. Discovered using a combination of lab experiments and computer
modelling, the new plastics have properties that could potentially have
a huge impact in manufacturing, transportation, aerospace, and micro
electronics.
Since the first synthetic plastics were invented in the 19th century,
the use of polymers has spread from artificial billiard balls to become
one of the key materials of the 21st century. They’re used so widely in
modern life that this could almost be called a plastic age, though the
names are rarely familiar with such non-household labels as polyesters,
polyacrylates, polyethylene, polyolefins, polystyrene, epoxies,
polyamides, and polyimides.
Despite this ubiquity, plastics aren't all that they should be. While
they have a reputation for indestructibility, they’re actually very
sensitive to the environment. Ultraviolet light, oxygen, heat, alcohols,
and solvents can all destroy plastics in short order. Try using a
polystyrene cup to measure out petrol and you’ll get a dramatic
demonstration of this. They’re also very difficult to recycle because
once they've been cured they can’t be remolded, and over time some can
exude toxic chemicals if left in a landfill.
Up until now, polymer chemistry was regarded as a mature field where
all the big discoveries have been made and it's now just a matter of
filling in the details. It’s been decades since the last family of
polymers was discovered, and most plastics research today involves
combining, tweaking, and generally learning how to work plastics. It’s a
bit like making advances in woodworking without discovering new species
of trees. Now IBM have discovered the first new family of trees ... or
rather, polymers in decades
We call chemistry a science, but in many ways it's an art that relies
on the experience and intuition of the chemist. Computational chemistry
combines the empirical work in the synthetic polymer chemistry lab with
the modelling power of the computer to predict chemical reactions. It
doesn't replace experiments, but it does cut out a lot of the trial and
error. And it’s through computational chemistry that the new polymers
were discovered.
The IBM polymers consist of two related classes of plastic materials.
They’re formed by combining paraformaldehyde and 4,4ʹ-oxydianiline in
what’s called a condensation reaction. When heated to 250⁰ C (482⁰ F)
the material becomes very strong as covalent bonds form and the solvent
is forced out, forming the first of two versions of the polymer. Both
versions are highly elastic, resistant to solvents, and are recyclable.
One version can even self-heal.
These polymers also show new physical properties. The first version is
lightweight, stiff, resistant to cracking, shows more strength than
bone, and can also turned into new polymer structures with half again as
much strength. However, it is very brittle, like glass. When mixed with
carbon nanofibers and heated, it forms an extremely strong, lightweight
composite material that is similar to metal, yet has a degree of
self-healing when cracked.
Another version of the plastic forms an elastic gel because it’s formed
at low temperature and traps the solvent in its molecular network. This
gel is not only very stretchy, but It’s “self-healing” because if you
cut a bit in two, they bond back together again in seconds when they
touch. According to IBM, this property makes the gel polymer useful as
an adhesive, a way of making other polymers self-healing, or as a method
for transporting dyes or medicines.
Both versions are also recyclable. Water doesn't affect the polymer,
but when the water is acidic, the polymer melts and can be recovered and
reformed into new products. This property means that the plastic can be
selectively removed without affecting surrounding materials, which has
great potential for the semiconductor industry, manufacturing, and
advanced composites.
“Although there has been significant work in high-performance
materials, today’s engineered polymers still lack several fundamental
attributes," says James Hedrick, Advanced Organic Materials Scientist,
IBM Research. "New materials innovation is critical to addressing major
global challenges, developing new products and emerging disruptive
technologies. We’re now able to predict how molecules will respond to
chemical reactions and build new polymer structures with significant
guidance from computation that facilitates accelerated materials
discovery. This is unique to IBM and allows us to address the complex
needs of advanced materials for applications in transportation,
microelectronic or advanced manufacturing.”
The IBM team’s research was published in Science.
The video below shows the new polymer in a lab setting.
Source: IBM
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