New
polymer additive could revolutionize plastics recycling
When
Geoffrey Coates, a professor of chemistry and chemical biology at Cornell
University, gives a talk about plastics and recycling, he usually opens with
this question: What percentage of the 78 million tons of plastic used for
packaging – for example, a 2-liter bottle or a take-out food container –
actually gets recycled and re-used in a similar way?
The
answer, just 2 percent. Sadly, nearly a third is leaked into the environment,
around 14 percent is used in incineration and/or energy recovery, and a
whopping 40 percent winds up in landfills.
One
of the problems: Polyethylene (PE) and polypropylene (PP), which account for
two-thirds of the world’s plastics, have different chemical structures and thus
cannot be repurposed together. Or, at least, an efficient technology to meld
these two materials into one hasn’t been available in the 60 years they’ve both
been on the market.
That
could change with a discovery out of Coates’ lab. He and his group have
collaborated with a group from the University of Minnesota to develop a
multiblock polymer that, when added in small measure to a mix of the two
otherwise incompatible materials, create a new and mechanically tough polymer.
EDITOR'S NOTE: Missing from this is any mention of potential health effects from the use of this new polymer. Previous miracle plastics, like Teflon, etc., were embraced and then found to be carcinogenic. Perhaps the timing of this new product announcement is an implied homage to the incoming Trump regime and their indifference to chemical safety. - W. Collette
EDITOR'S NOTE: Missing from this is any mention of potential health effects from the use of this new polymer. Previous miracle plastics, like Teflon, etc., were embraced and then found to be carcinogenic. Perhaps the timing of this new product announcement is an implied homage to the incoming Trump regime and their indifference to chemical safety. - W. Collette
Note: A video of the researcher explaining the study is available on YouTube. The video as well as graphics and the research paper can be downloaded at https://cornell.box.com/v/Polymer.
The
two groups’ work is detailed in a paper, “Combining polyethylene and
polypropylene: Enhanced performance with PE/iPP multiblock polymers,” published
online Feb. 23 in Science.
James
Eagan, a postdoctoral researcher in Coates’ group, is lead author of the paper.
Other collaborators included researcher Anne LaPointe and former visiting
scientist Rocco DiGirolamo.
Scientists
for years have tried to develop a polymer that does what Coates, LaPointe and
Eagan have achieved. By adding a miniscule amount of their tetrablock
(four-block) polymer – with alternating polyethylene and polypropylene segments
– the resultant material has strength superior to diblock (two-block) polymers
they tested.
In
their test, two strips of plastic were welded together using different
multi-block polymers as adhesives, then mechanically pulled apart. While the
welds made with diblock polymers failed relatively quickly, the weld made of
the group’s tetrablock additive held so well that the plastic strips broke
instead.
“People
have done things like this before,” Coates said, “but they’ll typically put 10
percent of a soft material, so you don’t get the nice plastic properties, you
get something that’s not quite as good as the original material.”
“What’s
exciting about this,” he said, “is we can go to as low as 1 percent of our
additive, and you get a plastic alloy that really has super-great properties.”
Not
only does this tetrablock polymer show promise for improving recycling, Eagan
said, it could spawn a whole new class of mechanically tough polymer blends.
“If
you could make a milk jug with 30 percent less material because it’s
mechanically better, think of the sustainability of that,” he said. “You’re
using less plastic, less oil, you have less stuff to recycle, you have a
lighter product that uses less fossil fuel to move it.”
Financial
support for the collaboration between Coates’ group and the group led by Frank
Bates, University of Minnesota professor of chemical engineering and materials
science, came from the Center for Sustainable Polymers, a National Science
Foundation (NSF) Center for Chemical Innovation.
Cornell
University has television, ISDN and dedicated Skype/Google+ Hangout studios
available for media interviews. For additional information, see this Cornell Chronicle story.
