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Beilstein J. Org. Chem. 2021, 17, 589–621, doi:10.3762/bjoc.17.53
Potential classification of plastic recycling processes. The area covered by the present review is ...
EG produced during glycolytic depolymerisation of PET using DEG + DPG as solvent and titanium(IV) n...
Simplified representation of the conversion of 1,4-PBD to C16–C44 macrocycles using Ru metathesis c...
Main added-value monomers obtainable by catalytic depolymerisation of PET via chemolytic methods.
Hydrogenolytic depolymerisation of PET by ruthenium complexes.
Depolymerisation of PET via catalytic hydrosilylation by Ir(III) pincer complex.
Catalytic hydrolysis (top) and methanolysis (bottom) reactions of PET.
Depolymerisation of PET by glycolysis with ethylene glycol.
Glycolysis of PET: evolution of BHET yield over time, with and without zinc acetate catalyst (196 °...
Potential activated complex for the glycolysis reaction of PET catalysed by metallated ILs and evol...
One-pot, two-step process for PET repurposing via chemical recycling.
Synthetic routes to PLA.
Structures of the zinc molecular catalysts used for PLA-methanolysis in various works. a) See , b) ...
Depolymerisation of PLLA by Zn–N-heterocyclic carbene complex.
Catalytic hydrogenolysis of PLA.
Catalytic hydrosilylation of PLA.
Hydrogenative depolymerisation of PBT and PCL by molecular Ru catalysts.
Glycolysis reaction of PCT by diethylene glycol.
Polymerisation–depolymerisation cycle of 3,4-T6GBL.
Polymerisation–depolymerisation cycle of 2,3-HDB.
Hydrogenative depolymerisation of PBPAC by molecular Ru catalysts.
Catalytic hydrolysis (top), alcoholysis (middle) and aminolysis (bottom) reactions of PBPAC.
Hydrogenative depolymerisation of PPC (top) and PEC (bottom) by molecular Ru catalysts.
Polymerisation-depolymerisation cycle of BEP.
Hydrogenolysis of polyamides using soluble Ru catalysts.
Catalytic depolymerisation of epoxy resin/carbon fibres composite.
Depolymerisation of polyethers with metal salt catalysts and acyl chlorides.
Proposed mechanism for the iron-catalysed depolymerisation reaction of polyethers. Adapted with per...
Beilstein J. Org. Chem. 2017, 13, 734–754, doi:10.3762/bjoc.13.73
Common reaction pathways for alkyne hydrogenation reactions.
Schematic representation of most common reactor types for batch and continuous-flow partial hydroge...
Schematic representation of flow regimes in microchannels; (a) bubbly flow, (b) slug/Taylor or segm...
Sketch of typical continuous flow apparatus for liquid-phase catalytic alkynes hydrogenation reacti...
Hydrogenation reactions of terminal alkynes with potential products and labelling scheme.
Structure of Pd@mpg-C3N4 (a), Pd(HHDMA)@C (b), Pd(Pb)@CaCO3 (c) and Pd@Al2O3 (d) catalysts. The str...
Sketch of composition (left) and optical image of Pd@MonoBor monolithic reactor (right). Adapted wi...
X-ray tomography 3D-reconstruction image of MonoBor . Unpublished image from the authors.
Representative TEM image of titanate nanotubes with immobilized PdNP (arrows). Adapted with permiss...
Conversion and selectivity vs. time-on-stream for the continuous-flow hydrogenation of 6 over Pd@Mo...
Continuous-flow hydrogenation of 3, 6 and 7 over different catalytic reactor systems. Data from ref...
Hydrogenation reactions of internal alkynes with potential products and labelling scheme.
Continuous-flow hydrogenation of 11 over Pd@MonoBor catalyst. a) Conversion and selectivity as a fu...
Conversion and selectivity vs time-on-stream for the continuous-flow hydrogenation of 11 over Pd@Mo...
Continuous-flow hydrogenation reaction of 11 over packed-bed catalysts. Adapted with permission fro...
Images of the bimodal TiO2 monolith with well-defined macroporosity: (a, b) optical; (c) X-ray tomo...
Selectivity of the continuous-flow partial hydrogenation reaction of 3 and 4 over packed-bed Pd cat...