From: American Chemical Society
January 27, 2021 -- Plastic is
ubiquitous in people's lives. Yet, when plastic-containing items have fulfilled
their missions, only a small amount is recycled into new products, which are
often of lower quality compared to the original material. And, transforming
this waste into high-value chemicals requires substantial energy. Now,
researchers reporting in ACS' JACS Au have combined a
ruthenium-carbon catalyst and mild, lower-energy reaction conditions to convert
plastics used in bottles and other packaging into fuels and chemical feedstock.
Global production of sturdy, single-use
plastic for toys, sterile medical packaging, and food and beverage containers
is increasing. Polyolefin polymers, such as polyethylene and polypropylene, are
the most common plastics used in these products because the polymers' molecular
structures -- long, straight chains of carbon and hydrogen atoms -- make
materials very durable. It's difficult to degrade the carbon-to-carbon bonds in
polyolefins, however, so energy-intensive procedures using high temperatures,
from 800 to 1400 F, or strong chemicals are needed to break down and recycle
them. Previous studies have shown that noble metals, such as zirconium,
platinum and ruthenium, can catalyze the process of splitting apart short,
simple hydrocarbon chains and complicated, plant-based lignin molecules at
moderate reaction temperatures requiring less energy than other techniques. So,
Yuriy Román-Leshkov and colleagues wanted to see if metal-based catalysts would
have a similar effect on solid polyolefins with long hydrocarbon chains,
disintegrating them into usable chemicals and natural gas.
The researchers developed a method to
react simple hydrocarbon chains with hydrogen in the presence of noble- or
transition-metal nanoparticles under mild conditions. In their experiments,
ruthenium-carbon nanoparticles converted over 90% of the hydrocarbons into
shorter compounds at 392 F. Then, the team tested the new method on more
complex polyolefins, including a commercially available plastic bottle. Despite
not pretreating the samples, as is necessary with current energy-intensive
methods, they were completely broken down into gaseous and liquid products
using this new method. In contrast to current degradation methods, the reaction
could be tuned so that it yielded either natural gas or a combination of
natural gas and liquid alkanes. The researchers say implementing their method
could help reduce the volume of post-consumer waste in landfills by recycling
plastics to desirable, highly valuable alkanes, though technology to purify the
products is needed to make the process economically feasible.
https://www.sciencedaily.com/releases/2021/01/210127140002.htm
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