Washington D.C.: The researchers have discovered a new method for upcycling low-value plastics into high-quality liquid products to improve current recycling methods. The catalytic method serves a one-two punch by removing plastic pollution from the environment and contributing to a circular economy. The Northwestern University, Argonne National Laboratory and Ames Laboratory led the multi-institutional team that developed the method.
Our team is delighted to have discovered this new technology that will help us get ahead of the mounting issue of plastic waste accumulation, said Northwestern’s Kenneth R. Poeppelmeier, who contributed to the research.
“Our findings have broad implications for developing a future in which we can continue to benefit from plastic materials, but do so in a way that is sustainable and less harmful to the environment and potentially human health,” added Kenneth.
Poeppelmeier is the Charles E. and Emma H. Morrison Professor of Chemistry at Northwestern’s Weinberg College of Arts and Sciences, director of Northwestern’s Center for Catalysis and Surface Science and member of Northwestern’s Program on Plastics, Ecosystems and Public Health.
Kenneth co-led the work with Aaron D. Sadow, a scientist in the Division of Chemical and Biological Sciences at Ames Laboratory, and Massimiliano Delferro, group leader of Argonne National Laboratory’s catalysis program.
The study published in the journal — ACS Central Science.
There are certain things we can do as a society to reduce consumption of plastics in some cases, Aaron D. Sadow said. But there will always be instances where plastics are difficult to replace, so we really want to see what we can do to find value in the waste.
While plastics can be melted and reprocessed, this type of recycling yields lower-value materials that are not as structurally strong as the original material. Examples include down-cycling plastic bottles into a moulded park bench.
We sought to recoup the high energy that holds those bonds together by catalytically converting the polyethylene molecules into value-added commercial products, Delferro said.
The catalyst consists of platinum nanoparticles (just two nanometers in size) deposited onto perovskite nanocubes, which are about 50-60 nanometres in size. The team chose perovskite because it is stable under the high temperatures and pressures and exceptionally good material for energy conversion.
To deposit nanoparticles onto the nanocubes, the team used atomic layer deposition, a technique developed at Argonne that allows precise control of nanoparticles.
Under moderate pressure and temperature, the catalyst cleaved plastic’s carbon-carbon bond to produce high-quality liquid hydrocarbons. These liquids could be used in motor oil, lubricants or waxes or further processed to make ingredients for detergents and cosmetics.
This contrasts commercially available catalysts, which generated lower quality products with many short hydrocarbons, limiting the products’ usefulness.
The catalytic method produced far less waste in the process. Recycling methods that melt plastic or uses conventional catalysts generate greenhouse gases and toxic by-products.