A one-step method enables scalable and more environmentally friendly production of plant-derived plastic monomers, paving the way towards the mass production of a sustainable alternative to petroleum-based materials.
An international team, including Kiyotaka Nakajima of Hokkaido University, Japan, and Emiel Hensen of Eindhoven University of Technology, the Netherlands, has developed an energy-efficient method to synthesize bioplastic ingredients. The new technology will contribute towards the realization of sustainable ‘green products’, such as completely biobased beverage bottles. This study was conducted jointly with Mitsubishi Chemical Corporation and the findings were published in ACS Catalysis.
Biobased plastics are emerging as a next generation material and are expected to replace petroleum-derived plastics. A plant-derived polyester, called polyethylene furanoate (PEF), is a promising 100% renewables-based polymer derived from plants that can replace the giant of the plastic industry, polyethylene terephthalate (PET), due to its better physical, mechanical and thermal properties. However, realizing large-scale PEF production is seriously hampered by an inefficient production of the monomers.
Aerobic oxidation of a biomass-derived substrate called HMF in methanol and ethylene glycol produces monomers called MFDC and HEFDC, respectively. They are recognized as crucial monomers in the manufacture of PEF, because polymerization of MFDC with ethylene glycol or self-condensation of HEFDC can yield high-quality PEF (Figure 1).
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Image: Reaction pathway for the production of MFDC and HEFDC from HMF (a conventional process) and HMF-acetal (new one-pot processes). (Credit: Kiyotaka Nakajima, Hokkaido University)