Influence of alumina pH on properties of Fe2O3/Al2O3 catalyst for high-density polyethylene decomposition to H2 generation
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M. Avalos-Borja | M. A. Armenta | L. A. Flores-Sánchez | J. M. Quintana-Melgoza | O. Jaime-Acuña | R. Obeso–Estrella
[1] Ningbo Gao,et al. Analysis of hydrogen production potential from waste plastics by pyrolysis and in line oxidative steam reforming , 2022, Fuel Processing Technology.
[2] Mebin Samuel Panithasan,et al. Pyrolysis plastic oil production and optimisation followed by maximum possible replacement of diesel with bio-oil/methanol blends in a CRDI engine , 2021 .
[3] A. Chopra,et al. Thermochemical Recycling of Waste Plastics by Pyrolysis: A Review , 2021, Energy & Fuels.
[4] J. M. Arandes,et al. Waste Refinery: The Valorization of Waste Plastics and End-of-Life Tires in Refinery Units. A Review , 2021, Energy & fuels : an American Chemical Society journal.
[5] F. Fantozzi,et al. Pyrolysis-catalysis of different waste plastics over Fe/Al2O3 catalyst: High-value hydrogen, liquid fuels, carbon nanotubes and possible reaction mechanisms , 2021 .
[6] A. Olivas,et al. Dimethyl ether production via methanol dehydration using Fe3O4 and CuO over γ–χ–Al2O3 nanocatalysts , 2020 .
[7] C. Tzoganakis,et al. A comprehensive review of global production and recycling methods of polyolefin (PO) based products and their post-recycling applications , 2020 .
[8] G. Rhee,et al. Effects of different Al2O3 support on HDPE gasification for enhanced hydrogen generation using Ni-based catalysts , 2020 .
[9] J. M. Arandes,et al. Co-cracking of high-density polyethylene (HDPE) and vacuum gasoil (VGO) under refinery conditions , 2020 .
[10] J. M. Arandes,et al. Assessing the potential of the recycled plastic slow pyrolysis for the production of streams attractive for refineries , 2019, Journal of Analytical and Applied Pyrolysis.
[11] Haiping Yang,et al. Investigation of nickel-impregnated zeolite catalysts for hydrogen/syngas production from the catalytic reforming of waste polyethylene , 2018, Applied Catalysis B: Environmental.
[12] O. Ogunola,et al. Mitigation measures to avert the impacts of plastics and microplastics in the marine environment (a review) , 2018, Environmental Science and Pollution Research.
[13] Haiping Yang,et al. Co-production of hydrogen and carbon nanotubes from real-world waste plastics: Influence of catalyst composition and operational parameters , 2018 .
[14] G. Lopez,et al. Valorisation of different waste plastics by pyrolysis and in-line catalytic steam reforming for hydrogen production , 2018 .
[15] Paul T. Williams,et al. Fe–Ni–MCM-41 Catalysts for Hydrogen-Rich Syngas Production from Waste Plastics by Pyrolysis–Catalytic Steam Reforming , 2017 .
[16] D. Hui,et al. Recycling of plastic solid waste: A state of art review and future applications , 2017 .
[17] M. Darwish,et al. Wax co-cracking synergism of high density polyethylene to alternative fuels , 2015 .
[18] Paul T. Williams,et al. Processing real-world waste plastics by pyrolysis-reforming for hydrogen and high-value carbon nanotubes. , 2014, Environmental science & technology.
[19] Hiroshi Katoh,et al. Acid properties of silica-alumina catalysts and catalytic degradation of polyethylene , 1993 .
[20] M. Schnitzer,et al. Effect of fulvic acid on the crystallization of aluminum hydroxides , 1980 .
[21] Tadashi Yoshida,et al. Gasification of Polyethylene over Solid Catalysts (Part 3) , 1979 .
[22] A. L. Patterson. The Scherrer Formula for X-Ray Particle Size Determination , 1939 .
[23] Yoshikazu Sugimoto,et al. Conversion of Polyethylene to Transportation Fuels through Pyrolysis and Catalytic Cracking , 1994 .