Chemical recycling of polyethylene terephthalate via glycolysis over NiMnAl catalysts: a comparison between coprecipitation and urea synthesis method
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recycling, PET, glycolysis, nickel, manganese, aluminium, coprecipitation, urea methodResumo
The reuse of Poly (ethylene terephthalate) - PET post-consumer residues is generally performed by mechanical processes. However, the quality of the resulting PET decreases after a limited number of reuses. Therefore, chemical “recycling”, especially glycolysis with ethylene glycol, allowing the formation of the monomer bis-2-hydroxy-ethyl terephthalate (BHET) is a useful alternative and the monomer can be used again to obtain higher PET purity. Nevertheless, the glycolysis reaction needs a catalyst, and heterogeneous materials have great interest since they promote easier separation and less BHET product contamination. Still, trimetallic combinations of mixed oxides are yet to be explored [1]. This study aimed to compare the influence of catalyst synthesis by coprecipitation and urea method on the properties of mixed oxides of Ni, Mn, and Al and their activity in PET glycolysis. The coprecipitation was conducted at a constant pH of 9 and 65°C. The precipitate was aged for 4h at 65°C and 18h at 25°C [2]. In the urea method, water, metal chlorides, ethylene glycol (EG), and urea were submitted to reflux (~90°C) for 24h and 18h at room temperature [3]. The precipitates in both methods were filtered, washed with boiling water, dried, and calcined at 600°C to obtain the catalysts. The precursors and catalysts were analyzed through XRD, TGA, FTIR, EDX, and N2 adsorption/desorption. The glycolysis tests were performed at 196°C, following a procedure described in [4], using a mass ratio EG: PET = 5:1, and catalyst: PET ratio of 0,005. The XRD results showed for the precursors a pattern associated with hydrotalcite and hausmannite (Mn3O4) for coprecipitation materials and rhodochrosite (MnCO3) for urea method. The catalyst prepared by the urea method displayed more crystalline phases like Mn2O3 than those resulting from the coprecipitation method. Nickel and aluminum were found in the NiO/NiAl2O4 phases. TGA and FTIR analyses corroborated that the precursors present the hydrotalcite phase and show an additional thermal transition related to the manganese oxidation into Mn2O3 in the case of the urea method. The specific surface area of the catalyst after the coprecipitation (170m2/g) was greater than that of the urea method (120 m2/g). The experimental composition of the mixed oxides was close to the theoretical one: Ni0.22Mn0.45Al0.33. Both catalysts displayed high activity, 100% PET conversion, and 85% BHET yield after 40 min reaction. This result shows that the synthesis method did not influence their catalytic properties, being then interchangeable. However, the coprecipitation presented three advantages over the urea method: i) its synthesis time is 24h against 42h, ii) the catalyst yield is greater, iii) the specific surface area is higher
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[1] J. Xin, Q. Zhang, J. Huang, R. Huang, Q.Z. Jaffery, D. Yan, Q. Zhou, J. Xu, X. Lu, Progress in the catalytic glycolysis of polyethylene terephthalate, J Environ Manage 296 (2021). https://doi.org/10.1016/j.jenvman.2021.113267.
[2] H. Blanco, S.H. Lima, V. de Oliveira Rodrigues, L.A. Palacio, A. da Costa Faro Jr., Copper-manganese catalysts with high activity for methanol synthesis, Appl Catal A Gen 579 (2019) 65–74. https://doi.org/10.1016/j.apcata.2019.04.021.
[3] M. Adachi-Pagano, C. Forano, J.P. Besse, Synthesis of Al-rich hydrotalcite-like compounds by using the urea hydrolysis reaction - Control of size and morphology, J Mater Chem 13 (2003) 1988–1993. https://doi.org/10.1039/b302747n.
[4] A.P. Arcanjo, D.O. Liborio, S. Arias, F.R. Carvalho, J.P. Silva, B.D. Ribeiro, M.L. Dias, A.M. Castro, R. Fréty, C.M.B.M. Barbosa, J.G.A. Pacheco, Chemical Recycling of PET Using Catalysts from Layered Double Hydroxides: Effect of Synthesis Method and Mg-Fe Biocompatible Metals, Polymers (Basel) 15 (2023) 3274. https://doi.org/10.3390/polym15153274.
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Copyright (c) 2024 Hezrom Saulo Nascimento, Celmy Maria Bezerra Menezes Barbosa, Roger Frety, Maria Fernanda Pimentel, José Geraldo Andrade Pacheco (Autor)
Este trabalho está licenciado sob uma licença Creative Commons Attribution 4.0 International License.
