Process optimization by NMR-assisted investigation of chemical pathways during depolymerization of PET in subcritical water?
Green Chemistry Pub Date: 2023-03-09 DOI: 10.1039/D2GC04831K
Abstract
Chemical recycling of polymers to monomers and chemicals is a promising pathway to valorize plastic waste that cannot be mechanically recycled, thus potentially minimizing resource consumption and the overall CO2 impact of the polymer industry. Among chemical recycling technologies, solvolytic depolymerization of poly(ethylene terephthalate) stands out as a selective process that maximizes monomer recovery. However, many challenges still remain regarding the optimization of these recycling technologies. Addressing these challenges could lead to these technologies becoming truly environmentally advantageous compared to alternative waste management solutions. Subcritical water has proven to be an outstanding media for a broad variety of reactions and its potential as a green solvent for PET depolymerization is reassessed based on a new nuclear magnetic resonance quantification method allowing for product characterization to a degree never reported before. In order to study the intrinsic product composition at every reaction condition (280 to 340 °C and 0 to 45 min reaction time), depolymerization experiments were performed in agitated micro-batch reactors, and NMR analysis was conducted prior to any alkaline-based purification. The highest recovery of terephthalic acid was achieved after 45 min at 340 °C, however, under these conditions ethylene glycol experiences a high degree of degradation. Collected data was then used to compare the environmental performance of different case scenarios leading to the preferable conditions to be 5 min at 310 °C, where the recovery of terephthalic acid, ethylene glycol, mono(2-hydroxyethyl) terephthalate and bis(2-hydroxyethyl) terephthalate is as high as 0.9 g g?1 PET.
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- [1] Estimates of hydride ion stability in condensed systems: energy of formation and solvation in aqueous and polar-organic solvents Craig A. Kelly,David R. RosseinskyPhys. Chem. Chem. Phys., 2001,3, 2086-2090 10.1039/B010092G
- [2] Enabling high-throughput single-animal gene-expression studies with molecular and micro-scale technologies Jason WanLab Chip, 2020,20, 4528-4538 10.1039/D0LC00881H
- [3] Fe(iii)-mediated isomerization of α,α-diarylallylic alcohols to ketones via radical 1,2-aryl migration? Ziyang Deng,Changwei Chen,Sunliang CuiRSC Adv., 2016,6, 93753-93755 10.1039/C6RA20007A
- [4] Exchanged ligands on the surface of a giant cluster: [(MoO3)176(H2O)63(CH3OH)17Hn](32 – n)– Chem. Commun., 1998, 1501-1502 10.1039/A801804I
- [5] Fc microparticles can modulate the physical extent and magnitude of complement activity? David White,Sean R. StowellBiomater. Sci., 2017,5, 463-474 10.1039/C6BM00608F
- [6] Emulsion soft templating of carbide-derived carbon nanospheres with controllable porosity for capacitive electrochemical energy storage? M. Zeiger,N. J?ckel,P. Strubel,L. Borchardt,R. Reinhold,W. Nickel,J. Eckert,V. Presser,S. KaskelJ. Mater. Chem. A, 2015,3, 17983-17990 10.1039/C5TA03730A
- [7] Enabling chloride salts for thermal energy storage: implications of salt purity? J. Matthew Kurley,Phillip W. Halstenberg,Abbey McAlister,Stephen Raiman,Richard T. MayesRSC Adv., 2019,9, 25602-25608 10.1039/C9RA03133B
- [8] Evolution of hierarchical porous structures in supramolecular guest–host hydrogels? Christopher B. Rodell,Christopher B. Highley,Minna H. Chen,Neville N. Dusaj,Chao Wang,Lin Han,Jason A. BurdickSoft Matter, 2016,12, 7839-7847 10.1039/C6SM01395C
- [9] Evolution study of photo-synthesized gold nanoparticles by spectral deconvolution model: a quantitative approach Chung-Sung Yang,Mong-Shian Shih,Fang-Yi ChangNew J. Chem., 2006,30, 729-735 10.1039/B516465F
- [10] Elusive 2-aminofuran Diels–Alder substrates for a straightforward synthesis of polysubstituted anilines? Ana G. Neo,Ana Bornadiego,Jesús Díaz,Stefano Marcaccini,Carlos F. MarcosOrg. Biomol. Chem., 2013,11, 6546-6555 10.1039/C3OB41411F
Journal Name:Green Chemistry
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CAS no.: 89640-58-4
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