Magnetically recyclable CoFe2O4 nanocatalysts for efficient glycolysis of polyethylene terephthalate
Abstract
Efficient and sustainable recycling of polyethylene terephthalate (PET) is essential in mitigating its environmental impacts on climate, human health, and global ecosystems. Glycolysis, a closed-loop recycling method that converts PET into bis(2-hydroxyethyl) terephthalate (BHET), stands out as one of the most promising methods due to its mild operating conditions and environmentally friendly nature. However, the complete convert PET into BHET with a high stability are still challenging. In this study, magnetically recyclable CoFe2O4 nanocatalysts were synthesized by the solvothermal method and surface-modulated with Na3Cit·2H2O as a modifier. When utilizing an optimized CoFe2O4 catalyst, conversion of PET achieved 100?%, with a BHET yield of 91.7?% at 210?°C for 1?h. The excellent catalytic performance of CoFe2O4 is attributed to its smaller particle size, improved dispersion, higher surface Co/Fe ratio, and increased oxygen vacancies, all of which can be achieved through straightforward surface modulation. DFT calculations of M?O distance (M = Co or Fe), adsorption energy, and Bader charges confirm that a higher surface Co/Fe ratio enhanced PET glycolysis, consistent with experimental results. Additionally, a modified energy economy coefficient (εm) was proposed to characterize the catalytic efficiency. The εm value of CoFe2O4-60?% was 0.624, indicating promising applications in efficient PET glycolysis. This work presents a versatile approach for easily manipulating the surface properties of magnetic catalysts and identifies key factors for achieving high performance in PET-to-BHET conversion. It offers valuable guidelines for the future design of nanoparticle catalysts with magnetic properties for chemocatalytic reactions.