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